Inorganic Compile
Transcript of Inorganic Compile
INORGANIC CHEMISTRY[Type the document subtitle][Type the abstract of the document here. The abstract is typically a short summary of the contents of the document. Type the abstract of the document here. The abstract is typically a short summary of the contents of the document.]
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PREFACE
Bismillahirrahmanirrahim.
Assalamu’alaikum Wr. Wb.
Alhamdulillahirabbil’alamin, praise and our thanks gives presence of God
who is praised and most high. that has gave us enjoy islam, enjoy faith and enjoy
healthy that no predicted. Shalawat and greeting not forgets us submit to our big
prophet, Mohammad saw that has brought us from stupidity era to science era.
We render thanks to the whole party that has supported and helped us
until we can finish this paper. Especially to both our old fellow, our lecturer Drs.
Agung Purwanto, M.Si., friends and other parties that can not we mention one by
one.
“Nothing are perfect except God.”. Maybe that words that can depict this
paper. Until we open our liver door to accept criticism and suggestion from all
parties, in order to later, in paper hereinafter can be better next.
And we apologize if existed insuffiency and mistake in this paper making.
Because all that correctness is only God property, and all wrong ones is ours
person.
Akhirul kalam.
Wassalamu’alaikum Wr. Wb.
Jakarta, October 2010
Chemistry 2009
COMPILERS
Atomic Theory and Elements Periodic System
1. Ratna Purnama Sari2. Sri Astriani3. Endah Dianty
Chemica Bonding and Molecular Geometry
1. Ulfah Choiriyah2. Sandra Masduroh3. Aditya Agam
Hybridization
1. Fitri Hartanti2. Sarah Yane Irene3. Selline Yansu
Groups IA and IB
1. Reni Andriani2. Putriningtias Imansari
Groups IIA and IIB
1. Sifa Fauziah Dwidara2. Ranie Pujiastuti
Groups IIIA and IIIB
1. Indah Budiarti2. Fenty Kanisateja3. Nurain Tri Rahayu
Groups IVA and IVB
1. Fitri Hartanti2. Sarah Yane Irene3. Selline Yansu
Groups VA and VB
1. Rully Putera S2. Lilis Septiarini3. Siti Lili A
Groups VIA and VIB
1. Rizqi Meidani F2. Mita Rahayu
Groups VIIA and VIIB
1. Mega Puspita S2. Christiandi Cahyo3. Syarifah Nabilah F
Groups VIIIA and VIIIB
1. Yulinar Eka P2. Apriyanti
Lantanide and Actinide
1. Taufik Triadi2. Zenith Tarra F3. Kartika Diah A
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LIST OF CONTENTS
Preface...................................................................................................................................
Compiler.................................................................................................................................
List of Contents.......................................................................................................................
Contents
Atomic Theory and Elements Periodic System............................................................1
Chemical Bonidng and Geometry Molecular.............................................................42
Hybridization.............................................................................................................80
Groups IA and IB......................................................................................................107
Groups IIA and IIB....................................................................................................147
Groups IIIA and IIIB..................................................................................................167
Groups IVA and IVB.................................................................................................207
Groups VA and VB...................................................................................................245
Groups VIA and VIB.......................................................................................................
Groups VIIA and VIIB.....................................................................................................
Groups VIIIA and VIIIB...................................................................................................
Groups Lantanide and Actinide.....................................................................................
1. CHAPTER 1
SOME FUNDAMENTAL CONCEPTS
Chemistry is the science that deals with the composition and
properties of substance and the transformations they undergo.
DIVISIONS OF CHEMISTRY
General Chemistry is a broad survey of chemistry as a whole, with
special emphasis on its basic principles and laws. It includes the
properties and reactions of some of the most common elements
and compounds.
Organic Chemistry is the study of compounds of carbon, either as
they are produced in plants and animals or as they are formed
synthetically.
Biochemistry is the study of the chemistry of living processes. All
the chemical reactions taking place in the body are more
specifically referred to as physiological chemistry.
Analytical chemistry is concerned with the methods of determining
the various constituents of matter as to what they are (qualitative
analysis), or how much they are (quantitative analysis). Physical
chemistry deals with the principles and laws that underlie chemical
changes.
Nuclear chemistry is the study of changes that take place in the
nucleus of the atom.
1.1 Matter
Matter is anything that occupies space and has mass. In
ordinary chemical reactions, matter can neither be created nor
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destroyed (law of conservation of matter). In nuclear reaction,
however, matter can be converted into energy, or vice versa.
Physical States of Matter, matter exists in three physical states:
solid, liquid, and gaseous, depending on temperature and pressure.
Solids are rigid and have a definite volume and a definite form.
Liquids have a definite volume but no definite form. They flow and
assume the shape of the vessel which holds them. Gases have
neither a definite volume nor a definite form. They diffuse into
every part of the container in which they are placed.
Classification of Matter. Matter can be in the form of an
element, a compound, or mixture.
Elements.
An element is a substance that cannot be decomposed into
simpler substance by ordinary chemical means. It may also be
defined as a substance whose properties give it a definite place in
the periodic table. There are 103 known chemical elements at the
present time. They may be classified into metals and nonmetals.
Examples of metals are iron, silver, and gold. Sulfur, oxygen and
nitrogen are nonmetals.
Compounds.
A compounds is made up of two or more elements chemically
combine in definite proportions by weight. Thus, the compound
water is composed of 11.11 percent hydrogen and 88.89 percent
oxygen by weight. A compound is homogeneous. Its properties are
quite different from those of its constituent elements, and its
constituent elements can be separated to oxygen in water
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illustrates the law of definite proportions, or the law of definite
composition.
Mixture.
A mixture is made up of two or more substance that are not
combined chemically. Its component parts retain their own
properties and can be separated by mechanical means. For
examples, cream of tartar baking powder is a mixture of sodium
bicarbonate, cream of tartar, and starch.
Changes in Matter.
Matter undergoes changes, some of which are physical and
others of which are chemical.
Physical changes. A physical change is an alteration in the
condition or state of substance. The chemical composition of the
substance is not changed. Examples of physical changes are the
chopping of wood, the breaking of glass, and the melting of ice.
Chemical Changes. A chemical change is one in which a new
substance is formed having a composition and properties different
from those of the original substance. For example, iron on exposure
to moist air becomes rust; sulfur, on burning, becomes sulfur
dioxide.
Properties of Matter.
The distinguishing characteristics of a substance are referred
to as its properties. There are two types of properties: physical
chemical.
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Physical Properties.
The physical properties of a substance are those associated with
physical changes. They include characteristics such as color, odor,
taste, density, crystalline form, boiling point, and melting point.
Chemical Properties.
Chemical properties are characteristics of elements and compounds
which describe the manner in which these substance react with
other substance. For example, sodium reacts readily with water to
liberate hydrogen; water is decomposed into hydrogen and oxygen
by electrolysis.
1.2 Energy
Energy may be defined as the ability to do work. Matter always
possesses energy in one form or another. All transformations of
matter are accompanied by transformations of energy.
Forms of Energy and Transformations. Energy can take many
forms; heat, light, electrical, kinetic, chemical, and nuclear or
atomic energy. Energy can be changed from one form to another
but cannot be created or destroyed in reactions other than nuclear
reactions (law of conservation of energy). For example, electricity is
changed into light in a light bulb; heat from steam is changed into
electricity in an electric generator.
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CHAPTER 2
ATOMIC THEORY
Birth of Atomic Theory
Modern chemistry is based on atomic theory. To understand
the atomic theory, first you must learn the fundamental laws
including the law of conservation of mass, comparative law remains,
and the law of multiple comparisons. These laws are basic atomic
theory and at the same time represent the conclusions drawn from
the theory of atoms. However, the atomic theory itself is
incomplete. Chemistry can be a consistent system since the atomic
theory combined with the concept of molecule. In the past, the
existence of an atom is only a hypothesis. In the early 20th century
atomic theory finally proved. It also became clear that the atom
consists of particles smaller. Current atomic theory is slowly
growing in line with this development and become a skeleton
material world.
2.1 Birth of chemical
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Modern chemistry initiated by the French chemist Antoine
Laurent Lavoisier (1743-1794). He discovered the law of
conservation of mass in chemical reactions, and reveal the role of
oxygen in combustion. Based on this principle, the chemistry
developed in the right direction.
Modern chemistry initiated by the French chemist Antoine
Laurent Lavoisier (1743-1794). He discovered the law of
conservation of mass in chemical reactions, and reveal the role of
oxygen in combustion. Based on this principle, the chemistry
developed in the right direction.
Actually, oxygen is found independently by two chemists, the
British chemist Joseph Priestley (1733-1804) and Swedish chemist
Carl Wilhelm Scheele (1742-1786), at the end of the 18th century.
Thus, only about two hundred years before the birth of modern
chemistry. Thus, chemistry is a relatively young science compared
to physics and mathematics, both have developed several thousand
years.
However, alchemy, metallurgy and pharmacy in ancient times
can be considered as the root chemistry. Many discoveries found
by people actively involved in all these areas contribute enormously
to modern chemistry, although alchemy was based on an incorrect
theory. Furthermore, prior to the 18th century, metallurgical and
pharmaceutical industries are actually based on experience rather
than theory. So, it seems unlikely this early points which later
evolved into modern chemistry. Based on these things and the
nature of modern chemistry is well organized and systematic
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methodology, real roots of modern chemistry may be found in
ancient Greek philosophy.
The road from the ancient Greek philosophy to modern atomic
theory is not always smooth. In ancient Greece, there is a sharp
dispute between the atomic theory and the denial of the existence
of atoms. Actually, the atomic theory remains the world's
unorthodox chemistry and science. Educated people are not
interested in atomic theory until the 18th century. At the beginning
of the 19th century, the British chemist John Dalton (1766-1844)
birth anniversary of ancient Greek atomic theory. Even after his
birth again, not all scientists accept the theory of atoms. Not until
the early 20th century theory of ato, finally proven as fact, not just
hypothetical. This is achieved by a skilled trial by the French
chemist Jean Baptiste Perrin (1870-1942). So, it took long enough
to establish the basis of modern chemistry.
2.1.1Ancient atomic theory
As noted earlier, the roots of modern chemistry is the atomic
theory developed by the ancient Greek philosopher. Atomic
philosophy of ancient Greece is often associated with Democritos
(roughly 460BC-roughly 370 BC). However, no posts Democritos
living. Therefore, we must be the source of the long poem "De
Rerum natura" written by the artists of the Roman Lucretius (about
1996 BC-about 55 BC).
Presented by Lucretius atom has similarities with modern
molecules. Grapes (wine) and olive oil, for example, has its own
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atoms. Atom is an abstract entity. Atom has a distinctive shape
with the corresponding function with form. "Atom wine was round
and smooth so it can pass through the esophagus with a smooth,
while the atoms of quinine rough and it would be difficult through
the esophagus." Molecule of modern structural theory states that
there is a very close relationship between molecular structure and
function.
Although the philosophy articulated by Lucretius is not
supported by evidence obtained from the experiment, this is the
beginning of modern chemistry.
In the long period from ancient times until the Middle Ages,
the theory of the atom In heretikal (berlwanan with commonly
accepted theory) because the theory of four elements (water, soil,
air and fire) the proposed Aristotole ancient Greek philosopher (384
BC-322 BC) charge of. When otortas Aristotle began to decline in
early modern centuries, many philosophers and scientists began to
develop theories that influenced the Greek atomic theory. Preview
the material retained by the French philosopher Rene Descartes
(1596-1650), German philosopher Gottfried Wilhelm Freiherr von
Leibniz (1646-1716), and British scientist Sir Isaac Newton (1642-
1727) more or less influenced by the theory of atoms.
2.1.2Dalton's atomic theory
At the beginning of the 19th century, atomic theory as a
philosophical matter has been well developed by Dalton who
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developed the atomic theory based on the role of atoms in chemical
reactions. The theory of atomic summarized as follows:
i. elementary particles that make up the elements are
atoms. All the atoms of certain elements are identical.
ii. the atomic mass of the same type will be identical but
different from other types of elements atomic mass.
iii. all atoms involved in chemical reactions. The whole
atom would form a compound. The type and number of
atoms in certain compounds remain.
The theoretical bases Dalton theory is primarily based on the
law of conservation of mass and tetap1 comparative law, both have
been found previously, and comparative law berganda2 developed
by Dalton himself. A particular compound always contain the same
element mass ratio.
Democritos atoms can be regarded as a kind of miniature
material. So the number of types of atoms will be equal to the
amount of material. On the other hand, Dalton's atoms are
constituents of matter, and many compounds can be formed by a
limited number of atoms. So, there will be a limited number of
types of atoms. Dalton's atomic theory requires a process of two or
more atoms combine to form the material. This is the reason why
atomic chemistry Dalton called atoms.
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Evidence of the existence of atoms
When Dalton proposed the atomic theory, theory attracted
considerable attention. However, this theory fails to receive full
support. Some supporters of Dalton made important efforts to
persuade against this theory, but some opposition persists.
Chemistry was not enough to prove the existence of atoms with the
experiment. So the atomic theory remains a hypothesis.
Furthermore, science after the 18th century developed a variety of
experiments that make many scientists became skeptical of the
atomic hypothesis. For example, such famous chemist Sir Humphry
Davy (1778-1829) and Michael Faraday (1791-1867), both from
England, both doubt on the theory of atoms.
While atomic theory remains a hypothesis, various dibuta
great progress in various fields of science. One of them is the rapid
emergence of thermodynamics in the 19th century. Structural
Chemistry at that time represented by the atomic theory is only a
matter of academic with little possibility of practical application.
But the thermodynamics derived from practical issues such as
efficiency of steam engines seem more important. There was a
sharp controversy between those supporting atomic
thermodynamics. The debate between Austrian physicist Ludwig
Boltzmann (1844-1906) and the German chemist Friedrich Wilhelm
Ostwald (1853-1932) with the Austrian physicist Ernst Mach (1838-
1916) deserves note. This debate is bad, Boltzmann committed
suicide.
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In the early 20th century, there were major changes in the
interest of science. A series of important discoveries, including
radioactivity, causing interest in the properties of atoms, and more
generally, structural science. That there are atoms in the
experiment was confirmed by sedimentation equilibrium
experiments by Perrin.
English botanist, Robert Brown (1773-1858) discovered
takberaturan motion of colloidal particles and the movement called
the motion Brown, in his honor. Swiss physicist Albert Einstein
(1879-1955) developed a theory based on the theory of atomic
motion. According to this theory, Brownian motion can be
expressed by an equation that contains Avogadro's number.
D = (RT / N). (1/6παη) ... (1.1)
D is the motion of particles, R gas constant, T temperature, N
Avogadro's number, α particle radius and η the viscosity of the
solution.
The core idea is as follows Perrin. Colloidal particles move
randomly by Brownian motion and simultaneously settle down by
the influence of gravity. Equilibrium sedimentation equilibrium
generated by these two motion, random motion and sedimentation.
Perrin carefully observe the distribution of colloidal particles, and
with the help of equation 1.1 and its data, he got the Avogadro's
number. Surprising value that matches the Avogadro's obtainment
obtained by other methods are different. This agreement further
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proves the truth of atomic theory that became the basis of the
theory of Brownian motion.
Not to mention, Perrin can not observe atoms directly. What
can be done at that time scientists, including Perrin, is to
demonstrate that Avogadro's number obtained from a number of
different methods based on the theory of identical atoms. In other
words they prove the theory of atoms indirectly with logical
consistency.
Within the framework of modern chemistry, such
methodology is still important. Even to this day still can not directly
observe atoms as small particles with the naked eye or microscope
optics. To observe directly with visible light, particle size must be
larger than the wavelength of visible light. The wavelengths of
visible light is in the range of 4.0 x 10 -7 - 7.0 x 10 -7 m, which
amount 1,000 times bigger than the size of atoms. So clearly
outside the range of optical equipment to observe the atom. With
the help of new tools such as electron microscopy (EM) or scanning
tunneling microscope (STM), this impossibility can be overcome.
Although the principle of observing the atom with this tool, in
contrast to what is involved with observing moon or interest, we can
say that we are now able to observe atoms directly.
2.1.3 JJ Thomson’s atomic theory
In early 1900 , J.J. Thomson proposed a new
atomic model that include the presence of particles
of electrons and protons . Since the experiments
show that protons have a mass far greater than the
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electron , Thomson described the model atoms as a single large
proton . In the particles of protons, electrons entering Thomson
neutralize the positive charge of protons . According to Thomson,
the atom consists of a sphere of positive charge is evenly
distributed with the meeting charge . On the positive charge is
spread electron with a negative charge , which represents the
positive charge . A popular way to describe this model is to consider
electrons as raisins ( plumb ) in the proton pudding cake , so this
model is given a raisin cake model ( plumb - pudding model).
Although Thomson's atomic model is the first which
incorporates the concept of the existence of protons and electrons
are charged , Thomson's model was not able to pass through the
observation of subsequent experiments . For the record, the protons
used in the Thomson model of the proton beam is not found in
more modern models .
In fact it can be said Thomson's model has no protons , but a
positively charged cells . Dalton atomic model of the influence can
be seen clearly in the Thomson model . Dalton speculated that
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atoms were solid, and Thomson supports this idea in his model of
electrons and protons by grouping together.
Catode tube x-ray
Thomson’s experiment to determine the ratio between and
electron’s mass (e/m).
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2.1.4Rutherford’s atomic theory
In 1910 , Ernest Rutherford experimented on the
truth of these models by conducting an
experiment now known as Rutherford scattering
( Rutherford scattering experiment ) .
Rutherford found a particle - α , a particle that is
emitted by radioactive atoms , in the year
1909 . These particles have a positive charge ,
and the fact is we now know that α -particles such as atoms of
helium released from the electron , giving the charge 2 +. In
scattering experiments , the flow of α particles is directed onto the
sheets of gold . This gold leaf is selected by Rutherford as it can be
made very thin - only a few atoms thick gold. When the particle - α
across the sheets of gold , Rutherford can measure how many α -
particles will be scattered by the gold atom by observing the flash
of light particles hit the screen scintilator - α .
Under the Thomson atomic theory , hypotesys of Rutherfod -
α particles will be deflected slightly , when the proton - α particles
of gold declined positively charged high.
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However, in reality , Rutherford scattering experiment showed
results clearly reject the hypothesis and of course the atomic model
of Thomson. Rutherfod found most alpha particles can penetrate to
slabs of gold without deflected . Simultaneously, Rutherford also
discovered that alpha particles deflected slightly , but with great
surprise , Rutherford also discovered that some alpha particles
deflected at a sharp angle back to the radioactive source .
To explain the existence of most of the α -particles which
penetrate the sheets of gold without deflected , Rutherford and
then develop a model of atomic nuclei. In this model , Rutherford
put a large proton ( such as experiments and previous models ) in
the center of the atom . Rutherford theorized that there are protons
around a large space that is empty of all particles except electrons
are rare . This large open space give the reason for the alpha
particles that are not unbending.
The alpha particles are estimated to have diverted some of the
protons pass close enough so that the deflected by electrostatic
forces . While some of the alpha particles deflected back to the
source is estimated to have undergone collisions with the core so
that reflected back by electrostatic forces .
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2.1.5Niels Bohr’s atomic theory
In 1913 Niels Bohr atom model Bohr tried to explain through
the concept that follow the orbits of electrons around the atomic
nucleus contains protons and neutrons . According to Bohr , there
are only a certain number of orbits , and the distinctions between
the orbit of one another is the orbital distance from the nucleus. The
existence of electrons in orbit either low or high
depending entirely by the electron energy levels .
So that the electrons in a low orbit will have less
energy than electrons in higher orbits .
Bohr's orbiting electrons and connecting
observations of gas through a spectrum of thought that some of the
energy contained in the electrons can be changed and therefore
electrons can change depending on the change of orbital energy. In
the current situation through the use of low pressure gas , the
electrons become de - excitation , and move to a lower orbit . In this
change, the electrons lose some energy which is the second energy
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level difference orbit. This emitted energy can be viewed in the
form of a photon of light wavelengths , based on the difference in
energy levels both orbits .
In short , Bohr submit :
1. Electrons in atoms move around the nucleus in certain paths ,
does not emit energy. electron trajectories are called skin or
electron energy levels .
2. Electrons can move from one trajectory to another trajectory .
3. Electron transfer from high to low energy levels with energy
transmitting . Being the displacement of electrons from low to
high levels of energy absorption with energy.
4. Electrons moving in an orbit is at a stationary state , meaning
that electrons do not emit or absorb energy.
Although the Bohr atom model sufficient to model the hydrogen
spectrum , the model proved not enough to predict a more complex
spectrum of elements
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2.1.6 James Chadwick’s atomic theory
In 1932 , Rutherford atomic model be modified slightly by
the discovery of the neutron by James Chadwick . Chadwick
found that α - particle bombardment of beryllium to produce
neutrons , uncharged particles , but with a mass slightly larger
than the proton mass . Thus , contemporary atomic model is a
model with a large nucleus which contains protons and
neutrons surrounded by a thin cloud of electrons. The presence
of neutrons also explains why the atomic mass is heavier than
the total mass of protons and electrons.
With a basic understanding of the fundamental parts of atoms
like electrons , protons , and neutrons , then it can be enabled by
the existence of more complex models and complete more than
enough atoms that can explain the nature and characteristics of
atoms and atomic compounds .
2.2 The birth of quantum mechanics
2.2.1The wave nature of particles
In the first half of the 20th century, began to note that the
electromagnetic waves, which were previously considered pure
wave, behaves like a particle (photon). French physicist Louis Victor
de Broglie (1892-1987) assumes that the opposite may also true,
namely materials also behave like waves. Starting from the
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Einstein equation, E = cp with p is the momentum of the photon, c
the speed of light and E is energy, he got the relationship:
E = hν = ν = c / λ or hc / λ = E, then h / λ = p ... (2.12)
De Broglie assumes each particle with momentum p = mv is
accompanied by a wave (wave of matter) with wavelength λ is
defined in equation (2.12) (1924). With the increasing size of the
particle, its wavelength becomes shorter. So to macroscopic
particles, particles, not possible to observe diffraction and other
phenomena associated with waves. For microscopic particles, like
electrons, the wavelength of the material can be observed. In fact,
electron diffraction patterns observed (1927) and prove the theory
of De Broglie.
2.1.7 Uncertainty principle
From what has been learned about the wave of the material, can
be observed that care must be taken when the macroscopic world
theory will be applied in the microscopic world. German physicist
Werner Karl Heisenberg (1901-1976) stated it is impossible to
determine accurately the position and momentum simultaneously
very small particles such electrons. To observe the particle, one
must radiate particles with light. Collisions between particles with
the photons will change the position and momentum of particles.
Heisenberg explained that the product of the uncertainty of the
position x and momentum uncertainties p would be worth about
Planck's constant:
λ p = h (2.13)
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This relationship is called the Heisenberg uncertainty principle.
2.2.2[2.2.3] Schrödinger equation
Austrian physicist Erwin Schrödinger (1887-1961) proposed the
idea that the De Broglie equation can be applied not only to the free
movement of particles, but also on movements such as electrons
bound in atoms. With wide this idea, he formulated the system of
wave mechanics. At the same time develop a system of
Heisenberg's matrix mechanics. Then the second day of this
system incorporated into quantum mechanics.
In quantum mechanics, the system state described by wave
functions. Schrödinger basing his theory on the idea that the
system total energy, E can be estimated by solving the equation.
Because this equation has a resemblance with the equation that
expresses the wave in classical physics, then this equation called
the Schrödinger wave equation.
Wave equations of particles (eg electrons) that move in one
direction (eg x-direction) is given by:
(-H 2 / 8π 2 m) (d 2 Ψ / dx 2) + VΨ = EΨ ... (2.14)
2.2.4 Quantum Number
Axial component of angular momentum are allowed only two
values, +1 / 2 (h/2π) and -1 / 2 (h/2π). Spin magnetic quantum
number associated with this value (m s = +1 / 2 or -1 / 2). Only the
spin quantum number alone in an amount not rounded.
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Table 2.3 Numbers of quantum
Name (quantum
number)
symbo
l
Values allowed
Main n 1, 2, 3, ...
Azimuth l 0, 1, 2, 3, ... n -
1
Magnetic m
(ml)
0, ± 1, ± 2 ,...±
l
Magnetic spin ms +1 / 2, -1 / 2
Other symbols as given in Table 2.4 are commonly used instead.
Hydrogen atom energy or hydrogen-like atom is determined only by
the principal quantum number and energy equations that express
identical to that already derived from the theory of Bohr.
Table 2.4 Symbols azimuth quantum number
value
0
1
2
3
4
symb
ol
s
p
d
f
g
22
Electron wave functions called orbital. When the main quantum
number n = 1, there is only one value of l, namely 0. In this case
there is only one orbital, and a collection of the orbital quantum
number for this is (n = 1, l = 0). When n = 2, there are two values
l, 0 and 1, are allowed. In case there are four orbital by defined set
of quantum numbers: (n = 2, l = 0), (n = 2, l = 1, m = -1), (n = 2, l
= 1, m = 0) , (n = 2, l = 1, m = +1).
2.2.5 Configuration Electron Atom
When atoms contained more than two electrons, the interaction
between electrons must be considered, and difficult to solve the
wave equation of this system is very complicated. With the
assumption that each electron in the poly-electron atom will move
in an electric field which is roughly symmetric orbital for each
electron can be defined by three quantum numbers n, l and m and
the number quantum spin m s, as in the case of hydrogen-like atom .
Hydrogen-like atomic energy is determined only by the principal
quantum number n, but for poly-electron atoms are mainly
determined by n and l. When the atoms have the same quantum
number n, the larger l, the higher the energy.
2.2.6 Pauli Exclusion Principle
According to the Pauli exclusion principle, only one electron in
an atom occupy permitted circumstances defined by a particular set
of four quantum numbers, or, at most two electrons can occupy an
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orbital which is defined by three quantum numbers n, l and m. The
two electrons that must have a value of m s are different, in other
words its spin antiparallel, and the pair of electrons is called with
a pair of electrons.
Groups of electrons with the same value of n is called with the skin
or skin electron. Notation used for the outer electrons are given
in Table 2.5.
Table 2.5 Symbols electron shells.
n
1
2
3
4
5
6
7
symbo
l
K
L
M
N
O
P
Q
Table 2.6 summarizes the maximum number of electrons in each
skin, skin from K to N. When the atoms in the most stable state, the
ground state, electrons will occupy the orbital with lowest energy,
following the Pauli principle.
Table 2.6 Maximum number of electrons that occupy each skin.
n
ski
n
l
symb
ol
Total
max
electron
total
skin
1
K
0
1s 2 (2 =
2x12)
L 2s 2 (8 =
24
2 0 2x22)
1
2p 6
3
M
0
3s 2 (18 =
2x32)
1
3p 6
2
3d 10
4
N
0
4s 2 (32 =
2x42)
1
4p 6
2
4d 10
3
4F 14
By increasing the orbital energy difference between the orbital
energy becomes smaller, and sometimes the sequence into the
outer shell inverted electrons . Configuration clearly change when
the atomic number changes. This is the basic theory of periodic
law.
It should be added here, using the symbols given in Table 2.6, the
electron configuration of atoms can published. For example,
hydrogen atoms in the ground state has one electron skin Diu K and
electron configuration (1s 1). The carbon atom has 2 electrons in the
25
skin of K and 4 electrons in the skin L. electron configuration is (1s 2
2s 2 2p 2).
CHAPTER 3
PERIODIC TABLE
Periodic Table
One of the greatest intellectual achievements in chemistry is
the periodic table of elements. The periodic table can be printed on
one sheet of paper, but what is contained in it and what can be
given to us very much and are invaluable. This table is the result of
tireless efforts, which originated from Greek times, to know the true
nature of matter. It can be said Shem chemical scripture. Value of
the periodic system not only on the information known to the
organization, but also its ability to predict the nature of the
unknown. Actual efficacy of the periodic table is located here.
3.1 The proposals before Mendeleev
26
The concept of elements is a very old concept, since the days
of Greece, the Greek philosopher said, the material is formed of four
elements: earth, water, fire and air. This view was gradually
abandoned, and finally in the 17th century definition of elements
given by the English chemist Robert Boyle (16,271,691) replaces
the old definition earlier. Boyle stated that the element is a
substance that can not be broken down into simpler substances.
Lavoisier proposed a list of elements in his book "Traite de
Chemie Elementire." Although he entered the light and heat in the
list, other members of the list is what we call the elements to date.
Besides, he added to the list of elements that have not been
detected, but he believed existed. For example, chlorine at that
time has not been isolated, but he added that to the table as a
radical from the acid muriatik. Similarly, sodium and potassium is
also in the table.
In the early 19th century, these elements were isolated by
electrolysis, and slowly expanded the list of elements. In the mid-
19th century, spectroscopic analysis, from method introduced
detecting element and accelerate the accretion of this list.
Although welcomed by chemists, emerging problems. One of the
questions was' Is a limited number of elements? " and another
question is' What is the nature of the elements expected to have a
certain order? "
The discovery of new elements catalysis discussions of this
kind. When iodine was found in 1826, German chemist Johann
Wolfgang Döbereiner (1780-1849) noted the similarity between this
27
element with elements that have been known to chlorine and
bromine. He also detects a trio of other similar elements. This is
what is known as the theory triade Döbereiner.
Table 3.1 Triade Döbereiner
lithium
(Li)
calcium
(Ca)
Chlorine
(Cl)
sulfur (S) manganese
(Mn)
Sodium
(Na)
strontium
(Sr)
Bromine
(Br)
selenium
(Se)
chromium
(Cr)
potassium
(K)
barium
(Ba)
iodine (I) tellurium
(Te)
Iron (Fe)
Octave Newland
In 1865, classifying the elements based on atomic mass
increases, but from the properties of these elements he observed a
repetition or periodic nature of the element. The nature of the
elements to 8 similar properties to-1 elements, so on the nature of
Element 9 has similar properties to the elements of the 2nd.
Because of the repetition of such nature, then it is called the Law of
Octaves. The following table law of octaves
Do Re Mi Fa Sol La Si
28
1 2 3 4 5 6 7H LI Be B C N OF NA Mg Al Si P SCl K Ca Cr Ti Mn FeCo,Ni Cu Zn Y In As SeBr Rb Sr Ce,La Zr Di, Mo Ro, RuPd Ag Cd U Sn Sb ITe Cs Ba Ta W Nb AuPt, Ir Os V Tl Pb Bi Th
Meyer
In 1864, Lothar Meyer conducted experiments that looked at
the relationship between the increase in atomic mass with element
properties. This is done by making the curve of atomic volume
versus atomic mass of atoms, showed chart below:
29
From these graphs, he noticed the regularity of the elements
with similar properties. For example, lithium (Li), Sodium (Na),
potassium (K), and Rubidium (Rb) is at the top. Even more
important is that he saw number elements among these peaks is
different. With it, repetition at the octave law does not apply.
3.2 Prediction Mendeleev and the truth
Many other elements grouping ideas put forward but does not
satisfy the scientific community that time. However, the theory
proposed by the Russian chemist Mendeleev Dmitrij Ivanovich
(1834-1907), and independently by the German chemist Julius
Lothar Meyer (1830-1895) is different from other proposals and
more persuasive. Both have the same views as follows:
30
Mendeleev and Meyer's view
1. List of elements that exist at that time might not yet
complete.
2. It is expected that the systematic nature of the elements
varies. So the nature of the unknown element can be
predicted.
At first the theory of Mendeleev failed to attract attention.
However, in 1875, indicated that the new element gallium was
discovered by French chemist Paul Emile Lecoq de Boisbaudran
(18,381,912) was not the other is the existence of eka -aluminum
and nature have been predicted by Mendeleev. Thus, the
significance of Mendeleev and Meyer's theory is slowly accepted.
Table 5.2 provides properties predicted by Mendeleev to the
elements when it is not known eka-silikon and properties of
germanium which was discovered by German chemist Clemens
Alexander Winkler (1838-1904).
Table 5.2 Prediction of the nature of eka-silicon elements by comparison with the nature of
Mendeleev and later found.
Nature eka-
silicon
germaniu
m
Relative atomic mass 72 72,32
Density 5,5 5,47
Atomic volume 13 13,22
Valence 4 4
31
Heat type 0,073 0,076
Meeting type dioxide 4,7 4,703
Tetrakhlorida Boiling
Point (° C)
<100 86
Mendeleev published a table which can be regarded as the origin of
the modern periodic table. In preparing the table, Mendeleev
initially arrange the elements in order of their atomic masses, as its
predecessor. However, he states preodic properties and sometimes
rearranging elements, resulting in reverse order of atomic mass.
Furthermore, the situation is complicated because the
procedures for determining the mass of the atom has not been
standardized, and sometimes chemists may use a different atomic
32
mass for the same element. This dilemma is slowly resolved after
the International Chemical Congress (Congress was held in 1860 in
Karlsruhe, Germany. The purpose of this congress to discuss the
problem of unification of atomic mass. Cannizzaro take this
opportunity to introduce the theory of Avogadro.) First, which was
attended by Mendeleev, but difficulties still exist.
By basing on the valence in determining the atomic mass,
Mendeleev bit much to solve the problem.
As has been described Sisem Modern Periodic periodic system is perfected that had been developed by Mendeleev, Similarity properties of the elements with electron configuration of elements, but it also turns out the elements in one group have the same valence electron. Here is a picture of modern periodic system
3.3 Periodic Table And Electron Configurations
33
The periodic table is continuously growing element of the
periodic table Mendeleev proposed. Meanwhile, there is a variety of
problems. One important issue is how to handle the noble gases,
transition elements and rare earth elements. All these
problems properly completed and make periodic table is more
valuable. Periodic table, chemical holy book, should be referred
routinely.
New class of noble gases easily inserted between the positive
elements of highly reactive, alkali metals (group 1) and negative
elements of highly reactive, halogen (group 7).
Accommodated the transition metal element in the periodic
table by inserting a long period despite reasonable not too clear.
The real problem is lantanoid. Lantanoid treated as an element of
"extra" and marginally placed outside the main part of the periodic
table. However, this procedure does not actually solve the main
problem. First, why this extra element is not clear, even more to
the puzzle is the question: is there a limit to the number of
elements in the periodic table? Because there are elements that
are very similar, very difficult to decide how many elements can
exist in nature.
Bohr theory and experiment Moseley generate theoretical
solution of this problem. Elucidation of the periodic table of the first
period until the third period can be explained by the theory of
electron configuration described in chapter 4. The first period (1 H
and 2 He) associated with the process of entering the 1s orbital.
Similarly, the second period (from 3 Li to 10 Ne) associated with
34
filling the orbital 1s, 2s and 2p, and 3rd period (from 11 Na to 18 Ar)
associated with filling the orbital 1s, 2s, 2p, 3s and 3p.
Long period begins the period of the 4th. The explanation for
this is because the d orbital of different shape drastically from the
circle, and a 3d electron energy is even higher than 4s.
Consequently, in the period-4, the electrons will fill the 4s orbital (19
K and 20 Ca) immediately after filling the 3s and 3p orbital, skip the
3d orbital. Then the electrons begin to occupy the 3d orbital. This
process is related to the ten elements from 21 Sc to 30 Zn. 4p orbital
subsequent charging process associated with the six elements of
the 31 Ga to 36 Kr. This is the reason why the period-4 contains 18
elements rather than 8. 4F orbital electron energy is much higher
than the 4d orbital electrons 4F and thus played no role in the
period-4 elements.
Period to period-5 is similar to the 4th. Electrons will fill the
orbital 5s, 4d and 5P in this order. As a result the period of the 5th
will have 18 elements. Orbital 4F not involved and this is what is
the reason why the number of elements in the 5 is 18.
The number of elements included in the 6 th period amounted
to 32 because 7x2 = 14 elements involved relating to the filling
orbital 4F. Initially the electrons fill the orbital 6s (55 Cs and 56 Ba).
Although there are miraculous exceptions, the element from 57 to 80
Hg La relating to charging and then orbital 5d 4F. Lantanoid series
(to 71 Lu) rare earth elements associated with orbital filling 4F. After
this process, six main group elements (81 to 86 Tl Rn) to follow, this is
related to charging 6p orbitas.
35
Period-7 to start with filling orbital 7s (87 Fr and 88 Ra), followed
by filling 5f orbital produce aktinoid series of rare earth elements
(from 89 Ac until the element number 103). World element will be
expanded further, but among the elements that exist naturally, the
element with the largest atomic number is 92 U. U is the element
after 92 artificial elements with a very short half-life. It is difficult to
predict the extension of the list of elements of this kind, but very
possibly a new element will be very short half-life.
In Table 3.3, summarized the relationship between the periodic
table and electron configuration.
Table 3.3 electron configuration of each period.
period filled
orbitals
number of
elements
1
(short)
1s 2
2
(short)
2s, 2p 2 + 6 = 8
3
(short)
3s, 3p 2 + 6 = 8
4
(long)
3d, 4s, 4p 2 + 6 + 10 = 18
5
(long)
4d, 5s, 5P 2 + 6 + 10 = 18
6
(long)
4F, 5d, 6s,
6p
2 + 6 + 10 + 14 =
32
36
3.4 The nature of the periodic elements
3.4.1 The First Ionization Energy
If these elements have been prepared in accordance with
their atomic mass, the nature of the element or compound showed
periodic, and this observation led to the discovery of the periodic
law. Electron configuration of elements to determine not only the
chemical properties of elements but also its physical properties.
The periodic clearly shown for the atomic ionization energy is
directly determined by the electron configuration. Ionization energy
is defined as the heat of reaction required to remove electrons from
neutral atoms, for example, for sodium:
Na (g) → Na + (g) + e-(5.1)
The first ionization energy, the energy required to move the
first electron, shows a very clear periodic as shown in figure 5.1.
For any period, the ionization energy increases with increasing
atomic number and reach the maximum of the noble gases. The
same group in ionization energy decreases with increasing atomic
number. Trends like this can be explained by the number of
valence electrons, the nuclear charge, and the number of electrons
inside.
The second and third ionization energy is defined as the energy
needed to move the second and third electron
37
3.4.2 Electron Affinity And Electronegative
Electron affinity is defined as the heat of reaction when the electron
is added to the neutral gas atoms, in the reaction.
F (g) + E ° → F ° (g) (5.2)
Positive values indicate exothermic reaction, endothermic
reaction negative. Because not too many atoms that can be added
electrons in the gas phase, the data is limited in number compared
to the amount of data for the ionization energy. Table 3.4 shows
that the greater electron affinity for the non-metals than for metals.
Table 3.4 Affinity-electron atoms.
H 72,4 C 122,5 F 322,3
Li 59, O 141,8 Cl 348,3
Na 54,0 P 72,4 Br 324,2
K 48,2 S 200,7 I 295,2
The amount electronegative (electrons) that is defined by
electronegative, which is a measure of atomic electron binding.
Chemists from the United States Robert Sanderson Mulliken (1896-
1986) defines electronegative comparable to the arithmetic
average of the ionization energy and electron affinity
Pauling electronegative defines the difference between the two
atoms A and B as the difference in binding energy diatomic
molecules AB, AA and BB. Assume D (AB), D (AA) and D (BB) is the
38
binding energy respectively for AB, AA and BB. D (AB) is greater
than the average geometry D (AA) and D (BB). This is due to
hetero-diatomic molecule is more stable than homo-diatomic
molecules due to the contribution of ionic structures. As a result, Δ
(AB), which is defined as follows, will be positive:
(AB) = D (AB) - √ D (AA) D (BB)> 0 (5.3)
(AB) will be greater with the growing ionic character. By using this
value, Pauling electronegative defines x as a measure of atom
attract the electron.
| X A-x B | = √ D (AB) (5.4)
x A and x B are the atoms A and B. electronegative
Whatever electronegative scale is chosen, it is clear that
electronegative increases from left to right and decreases from top
to bottom. electronegative very useful to understand the nature of
the chemical elements
Dipole direction can be represented with arrows that point to
a negative charge center with the beginning of the arrow centered
at the center of positive charge. Dipole magnitude, rq, called the
dipole moment. Dipole moment is a vector quantity and the
magnitude is μ and has a direction.
The amount of dipole moment can be determined by experiment,
but its direction can not be. Dipole moment of a molecule
39
(molecular dipole moment) is the resultant vector dipole moment of
existing bonds in the molecule. If there is symmetry in the
molecule, a large bond dipole moment can eliminate one another so
that the molecular dipole moment will be small or even zero.
3.4.3 The Oxidation Number Of Atoms
There is a clear relationship between oxidation number (or
oxidation) atom and its position in the periodic table. The oxidation
number of atoms in covalent compounds is defined as an imaginary
atomic charges to be acquired when the electron is shared equally
shared between bonded atoms (when atoms are bonded together)
or handed over all the atom the stronger the attraction (if different
atoms bonded .)
3.5 Main Group Elements
For main group elements, the oxidation state in most cases is
the number of electrons that will be released or received to achieve
the electron configuration management, ns 2 np 6 (except for the
first period) or electron configuration nd 10
This is obvious for elements of low periods that are members
of groups 1, 2 and 13-18. For larger periods, the tendency has
oxidation number associated with the electron with the electron
configuration ns np electron is maintained and will be released. For
example, tin Sn and Pb of lead, both class of 14, has a +2 oxidation
state with the release of electrons np 2 but retain ns 2 electrons, in
addition to oxidation state +4. The same reasons can be used to
the fact that the phosphorus P and bismuth Bi, both class 15 with
40
electron configuration ns 2 np 3, has an oxidation number of +3 and
+5.
Generally, the importance of electron oxidation with ns 2
maintained will become increasingly important for larger periods.
For nitrogen and phosphorus compounds, the dominant oxidation
state +5, while for bismuth is dominant is +3 and +5 oxidation
rather rare.
Metallic element and semilogam (silicon germanium Si or Ge)
rarely have a negative oxidation value, but for non-metals this
phenomenon is common. In the hydrides of nitrogen and
phosphorus, NH 3 and PH 3, the oxidation number of N and P is-3.
The higher the period of the element, the element will lose this trait
and bismuth Bi does not have the negative oxidation number.
Among the elements of group 16, the dominant oxidation state-2 as
in the case of oxygen O. This trend was again going down to the
elements in the period higher. Suppose that oxygen has only a
negative oxidation, but the S has a positive oxidation state +4 and
+6 are also significant.
3.6 Trasition Elements
Although the transition elements have multiple oxidation
states, regularity can be recognized. The highest oxidation number
of atoms that has five electrons ie the number of d orbitals
associated with the current state of all the d electrons (in addition
to electron s) issued. So, in the case of scandium with electron
41
configuration (n-1) d 1 ns 2, oxidation 3. Manganese with the
configuration (n-1) d 5 ns 2, will have maximum oxidation number
+7.
If the amount exceeds 5 d electrons, the situation changed.
For iron Fe with the electron configuration (n-1) d 6 ns 2, the main
oxidation state is +2 and +3. Very rare oxidation state +6. The
highest oxidation number of important transition metals like cobalt
Co, Nickel Ni, copper Cu and zinc Zn lower than the oxidation
number of atoms that lose all the electrons (n-1) d and ns his.
Among the elements that exist within the same group, the higher
the oxidation state is increasingly important for the elements in a
larger period.
The size of atoms and ions When Meyer atomic establish
volume is defined as the volume of 1 mole of a particular element
(atomic mass / density) against atomic number he got a saw tooth-
shaped plot. This clearly is evidence that the atomic volume shows
keperiodikan. Because a little difficult to determine the atomic
volume of all elements that are identical to the standard, this
correlation remains qualitative. However, Meyer's contribution in
drawing attention to the existence of atomic size periodic
noteworthy.
There are some commentators still double if you want to
specify the size of atoms because the electron clouds do not have
clear boundaries. For the size of metal atoms, we can determine the
radius of the atom by dividing the two distances between atoms, as
42
measured by X-ray diffraction analysis. It must be stated that this
value depends on crystal shape (eg a simple cubic lattice or a face-
centered cube, etc.) And this will produce a double interpretations
that. The same problem is also in the determination of ionic radii
are determined by X-ray diffraction analysis of ionic crystals.
periodic general tendency of the radius of atoms and ions. For
example, the radius of cation seperiode element will decrease with
increasing atomic number. This is logical because of the greater
nuclear charge will attract electrons more strongly. For ionic radius,
the larger the period the greater the radius of the ion.
43
Bibliography
Butler, Ian S, John F Harrord. 1989. Inorganic Chemistry
Principles and Application. California : The Benjamin or
Cummings
Chen, S. Phillip. 1979. Inorganic, Organic, and Biological
Chemistry. Second edition. United States of America :
Harper & Row, Publisher, Inc
F. Albert, Cotton etc. 1994. Basic Inorganic Chemistry.
Canada : John Wiley and Sons
J. Basset. 1965. Inorganic Chemistry a Concise text. Oxford
Pergamon Press
Therald Moeller. 1952. Inorganic Chemistry an Advance
Textbook. New York : John Wiley and Sons
http://wawanhar.wordpress.com/2010/01/05/konsep-dasar-atom/ 5:41 pm
44
CHEMICAL BONDING
Chemical bond refers to the forces holding atoms together to
form molecules and solids. This force is of electric nature, and the
attraction between electrons of one atom to the nucleus of another
atom contribute to what is known as chemical bonds. Although
electrons of one atom repell electrons of another, but the repulsion is
relatively small. So is the repulsion between atomic nuclei.
Various theories regarding chemical bond have been proposed
over the past 300 years, during which our interpretation of the world
has also changed. Some old concepts such as Lewis dot structure and
valency are still rather useful in our understanding of the chemical
properties of atoms and molecules, and new concepts involving
quantum mechanics of chemical bonding interpret modern
observations very well.
While reading this page, you learn new concepts such as
bondlength, bond energy, bond order, covalent bond, ionic bond, polar
and non-polar bond etc. These concepts help you understand the
material world at the molecular level.
Chemical bonds between identical atoms such as those in H2,
N2, and O2 are called covalent bonds, in which the bonding electrons
are shared. In ionic compounds, such as NaCl, the ions gather and
arrange in a systematic fashion to form a solid. The arrangement of
(blue) Na+ and (green) Cl- ions in a solid is shown in on the right here.
The attraction force between ions are called ionic bonding. Matals
such as sodium, copper, gold, iron etc. have special properties such as
being good electric conductors. Electrons in these solids move freely
throughout the entire solid, and the forces holding atoms together are
called metallic bonds. To some extend, metals are ions submerged is
electrons.
45
Though the periodic table has only 118 or so elements, there
are obviously more substances in nature than 118 pure elements. This
is because atoms can react with one another to form new substances
called compounds (see our Chemical Reactions module). Formed when
two or more atoms chemically bond together, the resulting compound
is unique both chemically and physically from its parent atoms.
Let's look at an example. The element sodium is a silver-
colored metal that reacts so violently with water that flames are
produced when sodium gets wet. The element chlorine is a greenish-
colored gas that is so poisonous that it was used as a weapon in World
War I. When chemically bonded together, these two dangerous
substances form the compound sodium chloride, a compound so safe that we
eat it every day - common table salt!
In 1916, the American chemist Gilbert Newton Lewis proposed
that chemical bonds are formed between atoms because electrons
from the atoms interact with each other. Lewis had observed that
many elements are most stable when they contain eight electrons in
their valence shell. He suggested that atoms with fewer than eight
valence electrons bond together to share electrons and complete their
valence shells.
While some of Lewis’s predictions have since been proven
incorrect (he suggested that electrons occupy cube-shaped orbitals),
his work established the basis of what is known today about chemical
46
bonding. We now know that there are two main types of chemical
bonding, ionic bonding and covalent bonding.
Why are carbon dioxide and sodium chloride so different? Why
can we divide compounds into two categories that display distinct
physical properties? The answers come from an understanding of
chemical bonds: the forces that attract atoms to each other in
compounds. Bonding involves the interaction between the valence
electrons of atoms. Usually the formation of a bond between two atoms
creates a compound that is more stable than either of the two atoms
on their own.
The different properties of ionic and covalent compounds result
from the manner in which chemical bonds form between atoms in
these compounds. Atoms can either exchange or share electrons.
When two atoms exchange electrons, one atom loses its valence
electron(s) and the other atom gains the electron(s). This kind of
bonding usually occurs between a metal and a non-metal. Metals have
low ionization energies and non-metals have high electron affinities.
That is, metals tend to lose electrons and non-metals tend to gain
them. When atoms exchange electrons, they form an ionic bond.
Atoms can also share electrons. This kind of bond forms
between two non-metals. It can also form between a metal and a non-
metal when the metal has a fairly high ionization energy. When atoms
share electrons, they form a covalent bond. How can you determine
whether the bonds that hold a compound together are ionic or
covalent? Examining the physical properties of the compound is one
method. This method is not always satisfactory, however. Often a
compound has some ionic characteristics and some covalent
characteristics. You saw this in the previous Thought Lab.
For example, hydrogen chloride, also known as hydrochloric
acid, has a low melting point and a low boiling point (It is a gas at room
temperature). These properties might lead you to believe that
hydrogen chloride is a covalent compound. Hydrogen chloride,
47
however, is extremely soluble in water, and the water solution
conducts electricity. These properties are characteristic of an ionic
compound. Is there a clear, theoretical way to decide whether the bond
between hydrogen and chlorine is ionic or covalent? The answer lies in
a periodic trend.
Predicting Bond Type Using Electronegativity
You can use the differences between electronegativities to
decide whether the bond between two atoms is ionic or covalent. The
symbol ΔEN stands for the difference between two electronegativity
values. When calculating the electronegativity difference, the smaller
electronegativity is always subtracted from the larger
electronegativity, so that the electronegativity difference is always
positive.
How can the electronegativity difference help you predict the
type of bond? By the end of this section, you will understand the aswer
to this question. Consider three different substances: potassium
fluoride, KF, oxygen, O2, and hydrochloric acid, HCl. Potassium fluoride
is an ionic compound made up of a metal and a non-metal that have
very different electronegativities. Potassium’s electronegativity is 0.82.
Fluorine’s electronegativity is 3.98. Therefore, ΔEN for the bond
between potassium and fluorine is 3.16.
Now consider oxygen. This element exists as units of two atoms
held together by covalent bonds. Each oxygen atom has an
electronegativity of 3.44. The bond that holds the oxygen atoms
together has an electronegativity difference of 0.00 because each
atom in an oxygen molecule has an equal attraction for the bonding
pair of electrons.
Finally, consider hydrogen chloride, or hydrochloric acid.
Hydrogen has an electronegativity of 2.20, and chlorine has an
48
electronegativity of 3.16. Therefore, the electronegativity difference for
the chemical bond in hydrochloric acid, HCl, is 0.96. Hydrogen chloride
is a gas at room temperature, but its water solution conducts
electricity. Is hydrogen chloride a covalent compound or an ionic
compound? Its ΔEN can help you decide, as you will see below.
A Brief Past on Chemical Bond Concepts
Various concepts or theories have been proposed to explain the
formation of compounds. In particular, chemical bonds were proposed
to explain why and how one element reacted with another element.
In 1852, E. Frankland proposed the concept of valence. He
suggested that each element formed compounds with definite amounts
of other elements due to a valence connection. Each element has a
definite number of valance.
Five years later, F.A. Kekule and others proposed a valence of 4
for carbon. Lines were used to represent valance, and this helped the
development of organic chemistry. The structure of benzene was often
quoted as an achievement in this development. More than 10 years
later, J.H. van't Hoff and le Bel proposed the tetrahedral
arrangement for the four valences around the carbon. These
theory helped chemists to describe many organic compounds. In the
mean time, chemical bonds were thaught to be electric nature. Since
electrons have not been discovered as the negative charge carriers,
they were thought to be involved in chemical bonds.
Following the discoveries of electrons by J.J. Thomson and R. A.
Millikan, G.N. Lewis proposed to use dots to represent valence
electrons. His dots made the valence electrons visible to chemists,
and he has been credited as the originator of modern bonding theory.
He published a book, in 1923, called Valence and the Structure of
Atoms and Molecules.
49
X-ray diffractions by crystal allow us to calculate details of
bondlength and bond angles. Using computers, we are able to
generate images of molecules from the data provided by X-ray
diffraction studies. These data prompted Linus Pauling to look at The
Nature of Chemical Bond, a book that introduced many new
concepts such as the resonance, electronegativity, ionic bond,
and covalent bond.
In England, N.V. Sidgwick and H.E. Powell paid their attention to
the lone pairs in a molecule. They developed the valence bond theory,
the VSEPR (Valence Shell Electron Pair Repulsion) theory. An excellent
summary of VSEPR is given on this link.
The application of quantum theory to chemical bonding gave
birth to a molecular orbital theory.
In this and the few following modules, we will look at some of
these concepts in detail.
Lewis Dot Structures
For the elements in the 2nd and 3rd periods, the number of
valence electrons range from 1 to 8. Lewis dot structure for them are
as indicated:
Using dots, Lewis made the valence electron visible. The
stability of noble gases is now associated with the 8 valence electrons
50
. . . . . . .. ..
Li Be .B. .C. .N: :O: :F : :Ne:
` ` ` ` ` ``
around it. The stability of 8 valence electrons led him to conclude that
all elements strive to acquire 8 electrons in the valence shell, and the
chemical reaction takes place due to elements trying to get 8
electrons. This is the octet rule. For the hydrogen and helium atoms,
2 electrons instead of 8 are required.
For example, the octet rule applies to the following molecules:
H : H
(2
electron
s)
.
.
H : O :
H
''
. .
H : F
:
''
H
. .
H : N :
H
' '
H
. .
H : C :
H
' '
H
:
N ::: N
:
.
. . .
: O ::
O :
.
. . .
: F : F
:
. .
. .
: O :: C ::
O :
To draw a Lewis dot structure, all the valence electrons are
represented. A good way is to draw a type of dot for the valence
electrons of one atom different from types in another. To do this on the
computer screen using only type fonts is difficult, but you should draw
a few by hand on paper.
When a dash is used to represent a bond, it represents a pair of
electrons. Thus, in the following representations, a dash represents two
electrons, bonding or lone pairs.
_ _ _
:S=O: :O:H :O
:H
These structures
satisfy
the octet rule. Note
the two ways of
drawing
51
| _ | | -
O :O:S:O: :O:O:
O:
" | " " | "
:O:H :O:H
" "
the structures of
H2SO4.
Ionic and Covalent Bonding: The Octet Rule
The physical properties of covalent and ionic compounds. You
learned how to distinguish between an ionic bond and a covalent bond
based on the difference between the electronegativities of the atoms.
By considering what happens to electrons when atoms form bonds, you
will be able to explain some of the characteristic properties of ionic and
covalent compounds.
The Octet Rule
Why do atoms form bonds? When atoms are bonded together,
they are often more stable. We know that noble gases are the most
stable elements in the periodic table. What evidence do we have? The
noble gases are extremely unreactive. They do not tend to form
compounds. What do the noble gases have in common? They have a
filled outer electron energy level. When an atom loses, gains, or shares
electrons through bonding to achieve a filled outer electron energy
level, the resulting compound is often very stable.
52
According to the octet rule, atoms bond in order to achieve an
electron configuration that is the same as the electron configuration of
a noble gas. When two atoms or ions have the same electron
configuration, they are said to be isoelectronic with one another. For
example, Cl− is isoelectronic with Ar because both have 18 electrons
and a filled outer energy level. This rule is called the octet rule because
all the noble gases (except helium) have eight electrons in their filled
outer energy level. (Recall that helium’s outer electron energy level
contains only two electrons.)
Elements in the 3rd and higher periods may have more than 8 valence
electrons. A possible explanation for this is to say that these atoms have d-type atomic
orbitals to accommodate more than 8 electrons. In the following molecules, the number
of valence electrons in the central atoms are as indicated:
MoleculeS
F6
P
Cl5
I
Cl3
X
eF4
No. of
valence
electrons
for
central
atom
1
2
1
0
1
0
1
2
Draw the Lewis dot structures for the above molecules, and
count the number of valence electrons for the central atoms. For
H2SO4, the S atom has 12 electrons in the structure shown on your
right. Each dash represent a chemical bond, which has two electrons.
There is a total of 6 bonds around the S atom, and
therefore 12 electrons.
53
OH
|
O=S=
O
|
OH
When B, Be, and some metals are the central atoms, they have
less than 8 valence electrons. The following compounds do form, but
the octet rule is not satisfied. These are electron defficient molecules.
MoleculeB
Cl2
B
F3
B
Cl3
S
nCl2
No. of
valence
electrons
for
central
atom
46
6
6
Isoelectronic Molecules and Ions
Counting the number of valence electrons often help us
understand the formation of many molecules and ions.
The charged molecule do exist under special circumstance.
The molecules of O2 are paramagnetic, and thus, they have
unpaired electrons. The first dot structure does not agree with this
54
observed fact, but the second one does. However, the second one does
not obey the octet rule.
Later, you will learn that the molecular orbital (MO) theory
provides a good explanation for the electronic configuration for O2.
Ionic Bonding
The electronegativity difference for the bond between sodium
and chlorine is 2.1. Thus, the bond is an ionic bond. Sodium has a very
low electronegativity, and chlorine has a very high electronegativity.
Therefore, when sodium and chlorine interact, sodium transfers its
valence electron to chlorine. Sodium becomes Na+ and chlorine
becomes Cl−. How does the formation of an ionic bond between sodium
and chlorine reflect the octet rule? Neutral sodium has one valence
electron. When it loses this electron to
chlorine, the resulting Na+ cation has an
electron energy level that contains eight
electrons. It is isoelectronic with the
noble gas neon. On the other hand,
chlorine has an outer electron energy
level that contains seven electrons.
When chlorine gains sodium’s electron,
it becomes an anion that is isoelectronic
with the noble gas argon. You can
represent the formation of an ionic bond
using Lewis structures.
Thus, in an ionic bond, electrons
are transferred from one atom to
another so that they form oppositely
charged ions. The strong force of
attraction between the oppositely charged ions is what holds them
together.
55
In ionic bonding, electrons are completely transferred from one
atom to another. In the process of either losing or gaining negatively
charged electrons, the reacting atoms form ions. The oppositely
charged ions are attracted to each other by electrostatic forces, which
are the basis of the ionic bond.
Notice that when sodium loses its one valence electron it gets
smaller in size, while chlorine grows larger when it gains an additional
valence electron. This is typical of the relative sizes of ions to atoms.
Positive ions tend to be smaller than their parent atoms while negative
ions tend to be larger than their parent. After the reaction takes place,
the charged Na+ and Cl- ions are held together by electrostatic forces,
thus forming an ionic bond. Ionic compounds share many features in
common:
Ionic bonds form between metals and nonmetals.
In naming simple ionic compounds, the metal is always first, the
nonmetal second (e.g., sodium chloride).
Ionic compounds dissolve easily in water and other polar
solvents.
In solution, ionic compounds easily conduct electricity.
Ionic compounds tend to form crystalline solids with high melting
temperatures.
This last feature, the fact that ionic compounds are solids,
results from the intermolecular forces (forces between molecules) in
ionic solids. If we consider a solid crystal of sodium chloride, the solid is
made up of many positively charged sodium ions (pictured below as
small gray spheres) and an equal number of negatively charged
chlorine ions (green spheres). Due to the interaction of the charged
ions, the sodium and chlorine ions are arranged in an alternating
fashion as demonstrated in the schematic. Each sodium ion is attracted
equally to all of its neighboring chlorine ions, and likewise for the
chlorine to sodium attraction. The concept of a single molecule does
not apply to ionic crystals because the solid exists as one continuous
56
system. Ionic solids form crystals with high melting points because of the strong
forces between neighboring ions.
Cl-1Na+
1 Cl-1Na+
1 Cl-1
Na+
1 Cl-1Na+
1 Cl-1Na+
1
Cl-1Na+
1 Cl-1Na+
1 Cl-1
Na+
1 Cl-1Na+
1 Cl-1Na+
1
Sodium Chloride Crystal
NaCl Crystal Schematic
Transferring Multiple Electrons
In sodium chloride, NaCl, one electron is transferred from
sodium to chlorine. In order to satisfy the octet rule, two or three
electrons may be transferred from one atom to another. For example,
consider what happens when magnesium and oxygen combine. The
electronegativity difference for magnesium oxide is 3.4 −1.3, 2.1.
Therefore, magnesium oxide is an ionic compound.
Magnesium contains two electrons in its outer shell. Oxygen
contains six electrons in its outer shell. In order to become
isoelectronic with a noble gas, magnesium needs to lose two electrons
and oxygen needs to gain two electrons. Hence, magnesium transfers
its two valence electrons to oxygen. Magnesium becomes Mg+2, and
oxygen becomes O2−.
Ionic Bonding That Involves More Than Two Ions
57
Sometimes ionic compounds contain more than one atom of
each element. For example, consider the compound that is formed
from calcium and fluorine. Because the electronegativity difference
between calcium and fluorine is 3.0, you know that a bond between
calcium and fluorine is ionic. Calcium has two electrons in its outer
energy level, so it needs to lose two electrons according to the octet
rule. Fluorine has seven electrons in its outer energy level, so it needs
to gain one electron, again according to the octet rule. How do the
electrons of these elements interact so that each element achieves a
filled outer energy level? In an ionic bond, calcium tends to lose two
electrons and fluorine tends to gain one electron.
Therefore, one calcium atom bonds with two fluorine atoms.
Calcium loses one of each of its valence electrons to each fluorine
atom. Calcium becomes Ca+2, and fluorine becomes F−. They form the
compound calcium fluoride, CaF2. In the following Practice Problems,
you will predict the kind of ionic compound that will form from two
elements.
Covalent Bonding
The second major type of atomic bonding occurs when atoms
share electrons. As opposed to ionic bonding in which a complete
transfer of electrons occurs, covalent bonding occurs when two (or
more) elements share electrons. Covalent bonding occurs because the
atoms in the compound have a similar tendency for electrons
(generally to gain electrons). This most commonly occurs when two
nonmetals bond together. Because both of the nonmetals will want to
gain electrons, the elements involved will share electrons in an effort
to fill their valence shells. A good example of a covalent bond is that
which occurs between two hydrogen atoms. Atoms of hydrogen (H)
have one valence electron in their first electron shell. Since the
capacity of this shell is two electrons, each hydrogen atom will "want"
58
to pick up a second electron. In an effort to pick up a second electron,
hydrogen atoms will react with nearby hydrogen (H) atoms to form the
compound H2. Because the hydrogen compound is a combination of
equally matched atoms, the atoms will share each other's single
electron, forming one covalent bond. In this way, both atoms share the
stability of a full valence shell.
Unlike ionic compounds, covalent molecules exist as true
molecules. Because electrons are shared in covalent molecules, no full
ionic charges are formed. Thus covalent molecules are not strongly
attracted to one another. As a result, covalent molecules move about
freely and tend to exist as liquids or gases at room temperature.
You have learned what happens when the electronegativity
difference between two atoms is greater than 1.7. The atom with the
lower electronegativity transfers its valence electron(s) to the atom
with the higher electronegativity. The resulting ions have opposite
charges. They are held together by a strong ionic bond.
What happens when the electronegativity difference is very
small? What happens when the electronegativity difference is zero? As
an example, consider chlorine. Chlorine is a yellowish, noxious gas.
What is it like at the atomic level? Each chlorine atom has seven
electrons in its outer energy level. In order for chlorine to achieve the
electron configuration of a noble gas according to the octet rule, it
needs to gain one electron. When two chlorine atoms bond together,
their electronegativity difference is zero. The electrons are equally
attracted to each atom. Therefore, instead of transferring electrons,
the two atoms each share one electron with each other. In other words,
each atom contributes one electron to a covalent bond. A covalent
bond consists of a pair of shared electrons. Thus, each chlorine atom
achieves a filled outer electron energy level, satisfying the octet rule.
When two atoms of the same element form a bond, they share
their electrons equally in a pure covalent bond. Elements with atoms
that bond to each other in this way are known as diatomic elements.
59
When atoms such as carbon and hydrogen bond to each other,
their electronegativities are so close that they share their electrons
almost equally. Carbon and hydrogen have an electronegativity
difference of only 2.6 −2.2, 0.4. One atom of carbon forms a covalent
bond with four atoms of hydrogen. The compound methane, CH4, is
formed.
Each hydrogen atom shares one of its electrons with the
carbon. The carbon shares one of its four valence electrons with each
hydrogen. Thus, each hydrogen atom achieves a filled outer energy
level, and so does carbon. (Recall that elements in the first period need
only two electrons to fill their outer energy level.) When analyzing
Lewis structures that show covalent bonds, count the shared electrons
as if they belong to each of the bonding atoms. In the following
Practice Problems, you will represent covalent bonding using Lewis
structures.
Multiple Covalent Bonds
Atoms sometimes transfer more than one electron in ionic
bonding. Similarly, in covalent bonding, atoms sometimes need to
share two or three pairs of electrons, according to the octet rule. For
example, consider the familiar diatomic element oxygen. Each oxygen
atom has six electrons in its outer energy level. Therefore, each atom
requires two additional electrons to achieve a stable octet. When two
oxygen atoms form a bond, they share two pairs of electrons. This kind
of covalent bond is called a double bond.
Double bonds can form between different elements, as well. For
example, consider what happens when carbon bonds to oxygen in
carbon dioxide. To achieve a stable octet, carbon requires four
electrons, and oxygen requires two electrons. Hence, two atoms of
oxygen bond to one atom of carbon. Each oxygen forms a double bond
with the carbon.
60
When atoms share three pairs of electrons, they form a triple
bond. Diatomic nitrogen contains a triple bond. Try the following
problems to practise representing covalent bonding using Lewis
structures.
For every pair of electrons shared between two atoms, a single
covalent bond is formed. Some atoms can share multiple pairs of
electrons, forming multiple covalent bonds. For example, oxygen
(which has six valence electrons) needs two electrons to complete its
valence shell. When two oxygen atoms form the compound O2, they
share two pairs of electrons, forming two covalent bonds.
Lewis dot structures are a shorthand to represent the valence
electrons of an atom. The structures are written as the element symbol
surrounded by dots that represent the valence electrons. The Lewis
structures for the elements in the first two periods of the periodic table
are shown below.
Lewis Dot Structures
Lewis structures can also be used to show bonding between
atoms. The bonding electrons are placed between the atoms and can
be represented by a pair of dots or a dash (each dash represents one
pair of electrons, or one bond). Lewis structures for H2 and O2 are
shown below.
H2 H:H
or
H-H
O2
61
Metallic Bonding
In this chapter, you have seen that non-metals tend to form
ionic bonds with metals. Non-metals tend to form covalent bonds with
other non-metals and with themselves. How do metals bond to each
other? We know that elements that tend to form ionic bonds have very
different electronegativities. Metals bonding to themselves or to other
metals do not have electronegativity differences that are greater.
Therefore, metals probably do not form ionic bonds with each
other. Evidence bears this out. A pure metal, such as sodium, is soft
enough to be cut with a butter knife. Other pure metals, such as
copper or gold, can be drawn into wires or hammered into sheets. Ionic
compounds, by contrast, are hard and brittle.
Do metals form covalent bonds with each other? No. They do
not have enough valence electrons to achieve stable octets by sharing
electrons. Although metals do not form covalent bonds, however, they
do share their electrons.
In metallic bonding, atoms release their electrons to a shared
pool of electrons. You can think of a metal as a nonrigid arrangement
of metal ions in a sea of free electrons. The force that holds metal
atoms together is called a metallic bond. Unlike ionic or covalent
bonding, metallic bonding does not have a particular orientation in
space. Because the electrons are free to move, the metal ions are not
rigidly held in a lattice formation.
Therefore, when a hammer pounds metal, the atoms can slide
past one another. This explains why metals can be easily hammered
into sheets. Pure metals contain metallic bonds, as do alloys. An alloy
is a homogeneous mixture of two or more metals. Different alloys can
have different amounts of elements. Each alloy, however, has a
uniform composition throughout. One example of an alloy is bronze.
Bronze contains copper, tin, and lead, joined together with metallic
bonds.
62
Polar and nonpolar covalent bonding
There are, in fact, two subtypes of covalent bonds. The H2
molecule is a good example of the first type of covalent bond, the
nonpolar bond. Because both atoms in the H2 molecule have an equal
attraction (or affinity) for electrons, the bonding electrons are equally
shared by the two atoms, and a nonpolar covalent bond is formed.
Whenever two atoms of the same element bond together, a nonpolar
bond is formed.
A polar bond is formed when electrons are unequally shared
between two atoms. Polar covalent bonding occurs because one atom
has a stronger affinity for electrons than the other (yet not enough to
pull the electrons away completely and form an ion). In a polar
covalent bond, the bonding electrons will spend a greater amount of
time around the atom that has the stronger affinity for electrons. A
good example of a polar covalent bond is the hydrogen-oxygen bond in
the water molecule.
Water molecules contain two hydrogen
atoms (pictured in red) bonded to one oxygen
atom (blue). Oxygen, with six valence electrons,
needs two additional electrons to complete its
valence shell. Each hydrogen contains one
electron. Thus oxygen shares the electrons from
two hydrogen atoms to complete its own valence
shell, and in return shares two of its own electrons with each hydrogen,
completing the H valence shells.
The primary difference between the H-O bond in water and the
H-H bond is the degree of electron sharing. The large oxygen atom has
a stronger affinity for electrons than the small hydrogen atoms.
Because oxygen has a stronger pull on the bonding electrons, it
preoccupies their time, and this leads to unequal sharing and the
formation of a polar covalent bond.
63
H2O: a water
molecule
When two bonding atoms have an electronegativity difference
that is greater than 0.5 but less than 1.7, they are considered to be a
particular type of covalent bond called a polar covalent bond. In a
polar covalent bond, the atoms have significantly different
electronegativities. The electronegativity difference is not great
enough, however, for the less electronegative atom to transfer its
valence electrons to the other, more electronegative atom. The
difference is great enough for the bonding electron pair to spend more
time near the more electronegative atom than the less electronegative
atom.
For example, the bond between oxygen and hydrogen in water
has an electronegativity difference of 1.24. Because this value falls
between 0.5 and 1.7, the bond is a polar covalent bond. The oxygen
attracts the electrons more strongly than the hydrogen. Therefore, the
oxygen has a slightly negative charge and the hydrogen has a slightly
positive charge.
Since the hydrogen does not completely transfer its electron to
the oxygen, their respective charges are not 1 and 1, but rather + and
-. The symbol + (delta plus) stands for a partial positive charge. The
symbol - (delta minus) stands for a partial negative charge.
The dipole
Because the valence electrons in the water molecule spend
more time around the oxygen atom than the hydrogen atoms, the
oxygen end of the molecule develops a partial negative charge
(because of the negative charge on the electrons). For the same
reason, the hydrogen end of the molecule develops a partial positive
charge. Ions are not formed; however, the molecule develops a partial
electrical charge across it called a dipole. The water dipole is
represented by the arrow in the pop-up animation (above) in which the
head of the arrow points toward the electron dense (negative) end of
the dipole and the cross resides near the electron poor (positive) end
of the molecule.
64
MOLECULAR GEOMETRY
Molecules are three-dimensional objects that occupy a three-
dimensional world, it is easy to forget this after seeing so many
depictions of molecular structures on a two-dimensional page. In
general, only the smallest molecules can be said to have a fixed
geometrical shape; the icosahedral C60 “soccer ball” is a rare
exception. In most molecules, those parts joined by single bonds can
rotate with respect to each other, giving rise to many different
geometric forms. However, the local ("coordination") geometry
65
surrounding a given atom that is covalently bound to its neighbors is
constant. Being able to understand and predict coordination geometry
is an important part of chemistry and is the subject of this section.
The Lewis electron-dot structures you have learned to draw
have no geometrical significance other than depicting the order in
which the various atoms are connected to one another. Nevertheless, a
slight extension of the simple shared-electron pair concept is capable
of rationalizing and predicting the geometry of the bonds around a
given atom in a wide variety of situations.
Electron-pair repulsion
The valence shell electron pair repulsion (VSEPR) model
that we describe here focuses on the bonding and nonbonding electron
pairs present in the outermost (“valence”) shell of an atom that
connects with two or more other atoms. Like all electrons, these
occupy regions of space which we can visualize as electron clouds—
regions of negative electric charge, also known as orbitals— whose
precise character can be left to more detailed theories.
The covalent model of chemical bonding assumes that the
electron pairs responsible for
bonding are concentrated
into the region of apace
between the bonded atoms.
The fundamental idea of
VSEPR thoery is that these
regions of negative electric
charge will repel each other, causing them (and thus the chemical
bonds that they form) to stay as far apart as possible. Thus the two
electron clouds contained in a simple triatomic molecule AX2 will
extend out in opposite directions; an angular separation of 180° places
the two bonding orbitals as far away from each other they can get. We
therefore expect the two chemical bonds to extend in opposite
directions, producing a linear molecule.
66
If the central atom also contains one or more pairs of
nonbonding electrons, these additional regions of negative charge
will behave very much like those associated with the bonded atoms.
The orbitals containing the various bonding and nonbonding pairs in
the valence shell will extend out from the central atom in directions
that minimize their mutual repulsions.
If the central atom possesses partially occupied d-orbitals, it
may be able to accommodate five or six electron pairs, forming what is
sometimes called an “expanded octet”.
Digonal and trigonal coordination
Linear molecules
As we stated above, a simple triatomic molecule of the type
AX2 has its two bonding orbitals 180° apart, producing a molecule that
we describe as having linear geometry.
Examples of triatomic molecules for which VSEPR theory
predicts a linear shape are BeCl2 (which, you will notice, doesn't
possess enough electrons to conform to the octet rule) and CO2. If you
write out the electron dot formula for carbon dioxide, you will see that
the C-O bonds are double bonds. This makes no difference to VSEPR
theory; the central carbon atom is still joined to two other atoms, and
the electron clouds that connect the two oxygen atoms are 180° apart.
Trigonal molecules
In an AX3 molecule such as BF3, there
are three regions of electron density
extending out from the central atom. The
67
repulsion between these will be at a minimum when the angle between
any two is (360° ÷ 3) = 120°. This requires that all four atoms be in the
same plane; the resulting shape is called trigonal planar, or simply
trigonal.
Tetrahedral coordination
Methane, CH4, contains a carbon
atom bonded to four hydrogens. What
bond angle would lead to the greatest
possible separation between the electron
clouds associated with these bonds? In
analogy with the preceding two cases,
where the bond angles were 360°/2=180°
and 360°/3=120°, you might guess
360°/4=90°, if so, you would be wrong.
The latter calculation would be correct if
all the atoms were constrained to be in the same plane (we will see
cases where this happens later), but here there is no such restriction.
Consequently, the four equivalent bonds will point in four
geometrically equivalent directions in three dimensions
corresponding to the four corners of a tetrahedron centered on the
carbon atom. The angle between any two bonds will be 109.5°.
This is the most important coordination geometry in Chemistry:
it is imperative that you be able to sketch at least a crude perspective
view of a tetrahedral molecule.
It is interesting to note that the tetrahedral coordination of
carbon in most of its organic compounds was worked out in the
nineteenth century on purely geometrical grounds and chemical
evidence, long before direct methods of determining molecular shapes
were developed.
For example, it was noted that there is only one
dichloromethane, CH2Cl2.
68
If the coordination around the carbon were square, then there
would have to be two isomers of CH2Cl2, as shown in the pair of
structures here. The distances between the two chlorine atoms would
be different, giving rise to differences in physical properties would
allow the two isomers to be distinguished and separated.
The existence of only one kind of CH2Cl2 molecule means that
all four positions surrounding the carbon atom are geometrically
equivalent, which requires a tetrahedral coordination geometry. If you
study the tetrahedral figure closely, you may be able to convince
yourself that it represents the connectivity shown on both of the
"square" structures at the top. A three-dimensional ball-and-stick
mechanical model would illustrate this very clearly.
Tetrahedrally-coordinated carbon chains
Carbon atoms are well known for their
tendency to link together to form the millions
of organic molecules that are known. We can
work out the simpler hydrocarbon chains by
looking at each central atom separately. Thus
the hydrocarbon ethane is essentially two CH3 tetrahedra joined end-to-
69
end. Similar alkane chains having the general formula H3C–(CH2)n–CH3
(or CnH2n+2) can be built up; a view of pentane, C5H12, is shown below.
Notice that these "straight chain hydrocarbons" (as they are
often known) have a carbon "backbone" structure that is not really
straight, as is illustrated by the zig-zag figure that is frequently used to
denote hydrocarbon structures.
Coordination geometry and molecular geometry
Coordination number refers to the number of electron pairs
that surround a given atom; we often refer to this atom as the central
atom even if this atom is not really located at the geometrical center of
the molecule. If all of the electron pairs surrounding the central atom
are shared with neighboring atoms, then the coordination geometry is
the same as the molecular geometry. The application of VSEPR theory
then reduces to the simple problem of naming (and visualizing) the
geometric shapes associated with various numbers of points
surrounding a central point (the central atom) at the greatest possible
angles. Both classes of geometry are named after the shapes of the
imaginary geometric figures (mostly regular solid polygons) that would
be centered on the central atom and would have an electron pair at
each vertex.
If one or more of the electron pairs surrounding the central
atom is not shared with a neighboring atom (that is, if it is a lone pair),
then the molecular geometry is simpler than the coordination
70
geometry, and it can be worked out by inspecting a sketch of the
coordination geometry figure.
Tetrahedral coordination with lone pairs
In the examples we have discussed so far, the shape of the
molecule is defined by the coordination geometry; thus the carbon in
methane is tetrahedrally coordinated, and there is a hydrogen at each
corner of the tetrahedron, so the molecular shape is also tetrahedral.
It is common practice to represent bonding patterns by
"generic" formulas such as AX4, AX2E2, etc., in which "X" stands for
bonding pairs and "E" denotes lone pairs. (This convention is known as
the "AXE method")
The bonding geometry will not be tetrahedral when the valence
shell of the central atom contains nonbonding electrons, however. The
reason is that the nonbonding electrons are also in orbitals that occupy
space and repel the other orbitals. This means that in figuring the
coordination number around the central atom, we must count both the
bonded atoms and the nonbonding pairs.
The water molecule: AX2E2
In the water molecule, the central
atom is O, and the Lewis electron dot
formula predicts that there will be two
pairs of nonbonding electrons. The oxygen
atom will therefore be tetrahedrally
coordinated, meaning that it sits at the
center of the tetrahedron as shown below.
Two of the coordination positions are
occupied by the shared electron-pairs that
constitute the O–H bonds, and the other
two by the non-bonding pairs. Thus
although the oxygen atom is tetrahedrally
coordinated, the bonding geometry
(shape) of the H2O molecule is described
as bent.
71
There is an important difference between bonding and non-
bonding electron orbitals. Because a nonbonding orbital has no atomic
nucleus at its far end to draw the
electron cloud toward it, the charge in
such an orbital will be concentrated
closer to the central atom. As a
consequence, nonbonding orbitals exert
more repulsion on other orbitals than do
bonding orbitals. Thus in H2O, the two
nonbonding orbitals push the bonding
orbitals closer together, making the H–O–H angle 104.5° instead of the
tetrahedral angle of 109.5°.
Although the water molecule is electrically neutral, it is not
electrically uniform; the non-bonding electrons create a higher
concentration of negative charge (blue color) at the oxygen end,
making the hydrogen side relatively positive (red).
Ammonia: AX3E
The electron-dot structure of NH3 places one pair of nonbonding
electrons in the valence shell of the nitrogen atom. This means that
there are three bonded atoms and one lone pair, for a coordination
number of four around the nitrogen, the same as occurs in H2O. We can
therefore predict that the three hydrogen atom will lie at the corners of
a tetrahedron centered on the nitrogen atom. The lone pair orbital will
point toward the fourth corner of the tetrahedron, but since that
position will be vacant, the NH3 molecule itself cannot be tetrahedral.
Instead, it assumes a pyramidal shape. More precisely, the shape is
that of a trigonal pyramid (i.e., a pyramid having a triangular base).
The hydrogen atoms are all in the same plane, with the nitrogen above
(or below, or to the side; molecules of course don’t know anything
about “above” or “below”!) The fatter orbital containing the non-
bonding electrons pushes the bonding orbitals together slightly,
making the H–N–H bond angles about 107°.
72
Central atoms with five bonds
Compounds of the type AX5 are formed by some of the
elements in Group 15 of the periodic table; PCl5 and AsF5 are examples.
In what directions can five electron pairs arrange themselves in
space so as to minimize their mutual repulsions? In the cases of
coordination numbers 2, 3, 4, and 6, we could imagine that the
electron pairs distributed themselves as far apart as possible on the
surface of a sphere; for the two higher numbers, the resulting shapes
correspond to the regular polyhedron having the same number of
sides.
The problem with coordination number 5 is that there is no
such thing as a regular polyhedron with five vertices.
In 1758, the great mathematian Euler proved that there are
only five regular convex polyhedra, known as the platonic solids:
tetrahedron (4 triangular faces), octahedron (6 triangular faces),
icosahedron (20 triangular faces), cube (6 square faces), and
dodecahedron (12 pentagonal faces). Chemical examples of all are
known; the first icosahedral molecule, LaC60 (in which the La atom has
20 nearest C neighbors) was prepared in 1986.
Besides the five regular solids, there can be 15 semi-regular
isogonal solids in which the faces have different shapes, but the vertex
angles are all the same. These geometrical principles are quite
important in modern structural chemistry.
The shape of PCl5 and similar
molecules is a trigonal bipyramid.
This consists simply of two
triangular-base pyramids joined
base-to-base. Three of the chlorine
atoms are in the plane of the central
phosphorus atom (equatorial
positions), while the other two atoms
are above and below this plane (axial positions). Equatorial and axial
73
atoms have different geometrical relationships to their neighbors, and
thus differ slightly in their chemical behavior.
In 5-coordinated molecules containing lone pairs, these non-
bonding orbitals (which you will recall are closer to the central atom
and thus more likely to be repelled by other orbitals) will preferentially
reside in the equatorial plane. This will place them at 90° angles with
respect to no more than two axially-oriented bonding orbitals.
Using this reasoning, we can predict that an AX4E molecule
(that is, a molecule in which the central atom A is coordinated to four
other atoms “X” and to one nonbonding electron pair) such as SF4 will
have a “see-saw” shape; substitution of more nonbonding pairs for
bonded atoms reduces the triangular bipyramid coordination to even
simpler molecular shapes, as shown below.
Octahedral coordination
Just as four electron pairs experience the minimum repulsion
when they are directed toward the corners of a tetrahedron, six
electron pairs will try to point toward the corners of an octahedron. An
octahedron is not as complex a shape as its name might imply; it is
simply two square-based pyramids joined base to base. You should be
able to sketch this shape as well as that of the tetrahedron.
The shaded plane shown in this
octahedrally-coordinated molecule is
only one of three equivalent planes
defined by a four-fold symmetry axis.
All the ligands are geometrically
74
equivalent; there are no separate axial and equatorial positions in an
AX6 molecule.
At first, you might think that a coordination number of six is
highly unusual; it certainly violates the octet rule, and there are only a
few molecules (SF6 is one) where the central atom is hexavalent. It
turns out, however, that this is one of the most commonly encountered
coordination numbers in inorganic chemistry. There are two main
reasons for this:
Many transition metal ions form coordinate covalent bonds with
lone-pair electron donor atoms such as N (in NH3) and O (in H2O).
Since transition elements can have an outer configuration of d10s2,
up to six electron pairs can be accommodated around the central
atom. A coordination number of 6 is therefore quite common in
transition metal hydrates, such as Fe(H2O)63+.
Although the central atom of most molecules is bonded to fewer
than six other atoms, there is often a sufficient number of lone pair
electrons to bring the total number of electron pairs to six.
Octahedral coordination with lone pairs
There are well known examples of 6-coordinate central atoms
with 1, 2, and 3 lone pairs. Thus all three of the molecules whose
shapes are depicted below possess octahedral coordination around the
central atom. Note also that the orientation of the shaded planes
shown in the two rightmost images are arbitrary; since all six vertices
of an octahedron are identical, the planes could just as well be drawn
in any of the three possible vertical orientations.
75
Summary of VSEPR
The VSEPR model is an extraordinarily powerful one,
considering its great simplicity. Its application to predicting molecular
structures can be summarized as follows:
1. Electron pairs surrounding a central atom repel each other; this
repulsion will be minimized if the orbitals containing these electron
pairs point as far away from each other as possible.
2. The coordination geometry around the central atom corresponds to
the polyhedron whose number of vertices is equal to the number of
surrounding electron pairs (coordination number). Except for the
special case of 5, and the trivial cases of 2 and 3, the shape will be
one of the regular polyhedra.
3. If some of the electron pairs are nonbonding, the shape of the
molecule will be simpler than that of the coordination polyhedron.
4. Orbitals that contain nonbonding electrons are more concentrated
near the central atom, and therefore offer more repulsion than
bonding pairs to other orbitals.
While VSEPR theory is quite good at predicting the general
shapes of most molecules, it cannot yield exact details. For example, it
does not explain why the bond angle in H2O is 104.5°, but that in H2S is
about 90°. This is not surprising, considering that the emphasis is on
electronic repulsions, without regard to the detailed nature of the
orbitals containing the electrons, and thus of the bonds themselves.
At this point we are ready to explore the three dimensional
structure of simple molecular (covalent) compounds and polyatomic
ions. We will use a model called the Valence Shell Electron-Pair
Repulsion (VSEPR) model that is based on the repulsive behavior of
electron-pairs. This model is fairly powerful in its predictive capacity.
To use the model we will have to memorize a collection of information.
The table below contains several columns. We already have a
concept of bonding pair of electrons and non-bonding pairs of
electrons. Bonding pairs of electrons are those electrons shared by the
central atom and any atom to which it is bonded. Non-bonding pairs of
76
electrons are those pairs of electrons on an individual atom that are
not shared with another atom.
In the table below the term bonding groups (second from the
left column) is used in the column for the bonding pair of electrons.
Groups is a more generic term. Group is used when a central atom has
two terminal atoms bonded by single bonds and a terminal atom
bonded with two pairs of electrons (a double bond).
In this case there are three groups of electrons around the
central atom and the molecualr geometry of the molecule is defined
accordingly. The term electron-pair geometry is the name of the
geometry of the electron-pairs on the central atom, whether they are
bonding or non-bonding.
Molecular geometry is the name of the geometry used to
describe the shape of a molecule. The electron-pair geometry provides
a guide to the bond angles of between a terminal-central-terminal
atom in a compound. The molecular geometry is the shape of the
molecule. So when asked to describe the shape of a molecule we must
respond with a molecular geometry.
# of lone pair electrons on
'central' atom
# of bonding groups (pair electrons) on
'central' atomElectron-pair
GeometryMolecular Geometry
BondAngle
0 2 linear linear 180
0 3trigonal planar
trigonal planar
120
1 2trigonal planar
bentless
than 120
0 4 tetrahedral tetrahedral 109.5
1 3 tetrahedraltrigonal
pyramidal
less than 109.5
2 2 tetrahedral bentless than 109.5
77
0 5trigonal
bipyramidaltrigonal
bipyramidal90, 120 and 180
1 4trigonal
bipyramidalseesaw
90, 120 and 180
2 3trigonal
bipyramidalT-shaped
90 and 180
3 2trigonal
bipyramidallinear 180
0 6 octahedral octrahedral90 and
180
1 5 octahedralsquare
pyramidal90 and
180
2 4 octahedralsquare planar
90 and 180
Note: for bent molecular geometry when the electron-pair
geometry is trigonal planar the bond angle is slightly less
than 120 degrees, around 118 degrees. For trigonal
pyramidal geometry the bond angle is slightly less than
109.5 degrees, around 107 degrees. For bent molecular
geometry when the electron-pair geometry is tetrahedral the
bond angle is around 105 degrees.
If asked for the electron-pair geometry on the central atom we
must respond with the electron-pair geometry. Notice that there are
several examples with the same electron-pair geometry, but different
molecular geometries. You should note that to determine the shape
(molecular geometry) of a molecule you must write the Lewis structure
and determine the number of bonding groups of electrons and the
number of non-bonding pairs of electrons on the central atom, then use
the associated name for that shape.
78
The table below summarizes the molecular and electron-pair
geometries for different combinations of bonding groups and
nonbonding pairs of electrons on the central atom.
Lets consider the Lewis structure for CCl4. We can draw the
Lewis structure on a sheet of paper. The most convenient way is shown
here.
Notice that
there are two kinds of
electron groups in
this structure.
Bonding electrons,
which are shared by a
pair of atoms and
nonbonding electrons,
which belong to a
particular atom but
do not participate
in bonding. In CCl4 the
central carbon atom has four bonding groups of electrons. Each
chlorine atom has three nonbonding pairs of electrons.
The arrangement of the atoms is correct in my structure. That
is the carbon is the central atom and the four chlorine atoms are
terminal. But this drawing does not tell us about the shape of the
molecule. Lets look at what I mean. Here we have a ball and stick
model of CCl4.
79
This is a nice representation of a two dimensional, flat
structure. The Cl-C-Cl bond angles appear to be 90 degrees. However,
the actual bond angles in this molecule are 109.5 degrees. What does
this do to our geometry?
Lets rotate this molecule to see what has happened. We see
the actual molecular geometry is not flat, but is tetrahedral. This ball
and stick model does not adequately represent why the molecule has
to have this 3-dimensional arrangement. The shape we see is the only
possible shape for a central carbon atom with four bonds. This
geometry is a direct result of the repulsion experienced by the four
groups of bonding electrons.
The shape of this molecule is a result of the electrons in the
four bonds positioning themselves so as to minimize the repulsive
80
effects. This was seen in the 'balloon' example we used in class. When
four balloons of the same size are tied together the natural
arrangement is as a tetrahedron. With bond angles of 109.5 degrees.
As indicated in Table I, any compound containing a central atom with
four bonding groups (pairs) of electrons around it will exhibit this
particular geometry.
By recognizing that electrons repel each other it is possible to
arrive at geometries which result from valence electrons taking up
positions as far as possible from each other. The position of the atoms
is dictated by the position of the bonding groups of electrons.
These ideas have been explored and have resulted in a theory
for molecular geometry known as Valence Shell Electron-Pair Repulsion
Theory.
VSEPR focuses on the positions taken by the groups of
electrons on the central atom of a simple molecule. The positions can
be predicted by imagining that all groups of electrons, whether they
are bonding pairs of electrons (single bonds), nonbonding pairs or
groups of electrons (multiple bonds) move as far apart as possible.
Arriving at the geometry of a molecules requires writing a
correct Lewis structure, determining the number of bonding groups
and nonbonding groups on the central atom of the molecule and then
recalling, from memory, the correct geometry based on the numbers of
bonding and nonbonnding groups of electrons.
Lone pairs of electrons are assumed to have a greater repulsive
effect than bonding pairs. Because of the nonbonding pairs of electrons
are spread over a larger volume of space compared to bonding
electrons. Because nonbonding electrons are spread over more space
they repel other electrons from a greater region of space. So it is more
favorable, energetically, for nonbonding pairs of electrons to be as far
away as possible from each other in space. So LP-LP repulsions are >
LP-BP repulsions > BP-BP repulsions.
This can be used to explain the change in bond angles
observed in going from methane to ammonia to water.
81
To predict the geometry of a molecule a reasonable Lewis
structure must be written for the molecule. The number of bonding and
nonbonding pairs of electrons on the central atom are then
determined. Let's progress, systematically, through the five basic
electron-pair geometries and detail the variations in molecular
geometries that can occur.
Two Electron Pairs (Linear)
The basic geometry for a molecule containing a central atom
with two pairs of electrons is linear. BeF2 is an example. Another
example of a linear compound is CO2. However, its Lewis structure
contains two double bonds. We need to recognize that multiple bonds
should be treated as a group of electron pairs when arriving at the
molecular geometry.
Three Electron Pairs (Trigonal Planar)
The basic geometry for a molecule containing a central atom
with three pairs of electrons is trigonal planar. BF3 is an example. If we
replace a bonding pair with a lone pair, as in SO2, the geometry is
described as bent or angular.
Four Electron Pairs (Tetrahedral)
The basic geometry for a molecule containing a central atom
with four pairs of electrons is tetrahedral. An example of this geometry
is CH4. As we replace bonding pairs with nonbonding pairs the
molecular geometry become trigonal pyramidal (three bonding and
one nonbonding), bent or angular (two bonding and two nonbonding)
and linear (one bonding and three nonbonding).
Notice that compounds with the same number of terminal
atoms, BF3 and NF3, do not necessarily have the same geometry. In this
case BF3 has three bonding pairs and no nonbonding pairs with a
geometry of trigonal planar, while NF3 has three bonding pairs and one
nonbonding pair with a geometry of trigonal pyramidal. Also note that
SO2 and H2O have a similar descriptor for their respective geometry.
Although each molecule can be described as having a bent geometry
the respective bond angles are different. For SO2 the O-S-O angle is
82
near 120 degrees, actually slightly less than 120, about 118 degrees,
for H2O the H-O-H angle is near 105 degrees.
Five Electron Pairs (Trigonal Bipyramidal)
The basic geometry for a molecule containing a central atom
with five pairs of electrons is trigonal bipyramidal. An example of this
geometry is PCl5. As we replace bonding pairs with nonbonding pairs
the molecular geometry changes to seesaw (four bonding and one
nonbonding), T-shaped (three bonding and two nonbonding) and linear
(two bonding and three nonbonding). This is an interesting system
because of the two different types of terminal atoms in the structure,
axial and equitorial. The equitorial terminal atoms are those in the
trigonal plane. The axial atoms are those above and below the trigonal
plane.
When the first bonding pair of electrons is replaced with a
nonbonding pair that occurs in the trigonal plane. the reason for this is
due to the smaller replusions between the lone pair and the bonding
pairs of electrons. If the lone pair replaced an axial atom the repulsions
would be greater. So as the bonding pairs of electrons are replaced
with nonbonding pairs the equitorial atoms are replaced. So as we
move from trigonal bipyramidal to linear the nonbonding pairs of
electrons occupy the equitorial plane, not the axial positions.
Six Electron Pairs (Octahedral)
The basic geometry for a molecule containing a central atom
with six pairs of electrons is octahedral. An example of this geometry is
SF6. As we replace bonding pairs with nonbonding pairs the molecular
geometry changes to square pyramidal(five bonding and one
nonbonding) to square planar (four bonding and two nonbonding).
There are no other combinations of bonding groups and nonbonding
pairs of electrons when the electron-pair geometry is octahedral. The
replacement of the first bonding group can occur in any position and
always produces a square pyramidal molecular geometry. However the
seond bonding group replaced is always opposite the first producing
the square planar molecular geometry.
83
REFERENCES
Basset, J. 1965. Inorganic Chemistry: A Concise Text/ J. Basset. Oxford:
Pergamon Press.
Butler, Ian S. 1989. Inorganic Chemistry Principle and Aplication.
California: The Benjamin Cummings.
Cotton, F. Albert, etc. 1994. Basic Inorganic Chemistry Third Edition.
Canada: John Wiley & Sons, Inc.
Moeller, Therald. 1952. Inorhanic Chemistry: An Advance
Textbook/Therald Moeller. New York: John Willey & Sons, Inc.
Purcell, Keith F, etc. 1982. An Introduction to Inorganic Chemistry.
Tokyo: Holt-Saunders Japan.
84
INTRODUCTION
Berilium khlorida BeCl2 and stanium (II) khlorida SnCl2 property of structure is
looking like because having molecule formula is looking like. But, simply having
structure first compound is linear is secondly curving. This thing is explainable with
difference of orbital atomic of applied. If electrons fills orbital atomic of to follow
principle Aufbau, electron will field orbital atomic of having low energy. Two
electrons is permitted to fills orbital one. According to principle Pauli, there is no
electron having an set of same correct quantum number of problem is arising is will
is put down where electron four carbon atom. Has been contended that low electron
configuration of atom is configuraton with number of couple electrons does is note
is maximum and still permitted by order Pauli indium setting orbital is of with the
same energy ( indium carbon case is orbital three of of 2p). Indium this case initially
all electrons will bound the same spin quantum number ( namely, + 1/2 or - 1/2)
Berilium is atom with two valence electrons and electron configuration ( 1s2
2s2). That having ilium forms tying as atom divalen, orbital of 2s and 2p must form
orbital couple are hybridization sp. Because second orbital hibrida sp forms angle of
tying 180°, Becl2 thereby linear
Theoritical of VSEPR and also hybridization of atomic orbital will give
conclusion of the same molecule structure and ion. Although the theory VSEPR only
base on jerk between electron pairses, and the hybridization theory gives his
theoretical justifikasi.
85
DISCUSSION
I. Devinisi Hybridization
Hybridization is a concept coalesces it is orbital is atoms forms new hybrid
orbital matching with qualitative explanation of atomic bond character. Orbital
concept hybridization very useful in explaining form of molecular orbital from a
molecule. The hybridization theory developed by chemistry Linus Pauling in
explaining molecule structure like methane (CH4).
In hybridization case that is simple, this approach based on orbital of
hydrogen atom. Orbital hybridization assumed as aliance from orbital of atom which
overlap one other same with proportion varying.
Orbital mixture of sulfur and p at the same atom is equivalent with one
orbital p. Result of his is visible in picture 1(b) constructive effect happened in
direction of orbital phase of sulfur and p berimpit, whereas the mixing effect is
destructive in direction which at the oposite. This effect yields big lobe at direction
as of phase together with small lobe in opposite orientation. Improvement of a kind
86
of this direction character related to the same atomic orbital mixture yields is orbital
with higher level direction called as hybridization, and yielded to be orbital called as
to be orbital hybridization or hybrid orbital.
Picture 1. The same atomic orbital mixing effect. ( a) change of direction to orbital
mixture of p with different direction. ( b) Improvement of direction to orbital mixture
of sulfur and orbital of p ( hybridization effect).
Hybrid orbital measures up to important following relating to chemical bond forming
:
1. Directivity becomes higher, and overlap with species coming from the
direction increases
2. Distribution hybrid orbital electron to become asymetric, and closeness of
electron at direction of improvement becomes excelsior to become strong
attractive force between this cores with near core.
87
a. Hybridization sp3
Hybridization explains atoms tying from the aspect of approach an atom. For
a co-ordinating carbon in tetrahedal ( like methane, CH4), hence carbon shall have is
orbital having correct symmetry with 4 hydrogen atom. Carbon ground state
configuraton is 1s2 2s2 2px1 2py1.
Valence bond theory predicts, based on at existence two orbital of p loaded
by half, that C will form two covalent bonds, that is CH2. But, methylene is a real
reactive molecule, so that just valence bond theory insufficient to explain existence
CH4.
Orbital of ground state cannot be applied for tying in CH4. Although excitation
of electron 2s to orbital of 2p theoretically permits four tyings and as according to
valence bond theory, this thing means there will be some tyings CH4 having
different binding energy because of difference of orbital overlap level.
This idea has been refuted experimentally, every hydrogen at CH4 can be
discharged from carbon with the same energy. To explain existence of this CH4
molecule, hence the hybridization theory applied. Initial step of hybridization is
excitation out of one ( or more) electron. Proton forming hydrogen atomic nucleus
will draw one of carbon valence electron. This thing causes excitation, removes
electron 2s to orbital of 2p. This thing increases atomic nucleus influence to valence
electrons by increasing effective nuclear potential.
Hybridization process of Methane gaseous molecules (CH4), atom has atom
configuraton H: 1s1 and atom configuraton C: 1s2 2s2 2Px1 2py1 2pz0.
88
In banding 4 atom H to become CH4, hence 1 electron ( orbital of 2s) from atom C
will be promoted into orbital of 2pz, so that the electron configuration becomes: 1s2
2s1 2px1 2py1 2pz1
Change happened covers orbital 1 of 2s and orbital 3 of 2p, hence called as
hybridization sp3. If hybrid orbital sp3 makes four tyings? with other species, this
orbital will yield molecule tetrahedral like CH4, SiH4, NH4 with angle of tetrahedral
bond 109,47º. Strength of tying for relative orbital fourth of equivalent, like picture
2. Molecule structure tetrahedral enough stable, so that many molecules having this
structure.
89
Picture 2. Form of molecule with hybridization sp3
Theoritical of orbital hybridization, methane valence electrons ought to have
the same energy level, but the fotoelekron spectrum indicating that there are two
ribbons, one by 12,7 eV ( one electron pairses) and one by 23 eV ( three electron
pairses). This explainable un-consistency if assuming existence of additional orbital
merger happened when orbital of sp3 joints forces with orbital 4 of hydrogen.
Picture 3. Ethane Structure ( CH3-CH3)
Sigma bond (σ) formed by every tip of overlap. Molecule giration can around angle
of tying.
90
b. Hybridization sp2
Ethylene (C2H4) has double bond two among the carbons. Carbon will did
hybridization sp2 because orbtial hybrid will only form sigma bond and one pi bonds
like the one required for double bond two among carbons. Tying hidrogen-karbon
has the same length and bond strength.
In hybridization sp2, orbital of 2s only joint forces with two orbital of 2p forms
orbital 3 of sp2 with one orbital of p remains. In ethylene, two carbon atoms forms a
sigma bond with overlap with two orbital of sp2 other carbon and every carbon
forms two covalent bonds with hydrogen with overlap s-sp2 which is angular 120°. Pi
bond between vertical carbon atoms with molecule area and formed by overlap 2p-
2p ( but, pi bond may happened and also no).
Hybridization process sp2, simply through phase as follows. Electron residing
in at orbital of 2s promoted and made a move at orbital of 2Py.
91
So is formed hybrid orbital sp2, what can react with other atom by forming
tying which approximately equal. Orbital of p which is not is hybridization to earns
overlap yields second tying, tying π. Tying π overlap aside, happened at top and
under from molecule.
Picture 3. Bonding At Ethene
c. Hybridization sp
92
Chemical bond in compound like alkyne with triple bond is explained with
hybridization sp. In modeling this, orbital of 2s only joint forces with one orbital-p,
yields two orbital of sp and leaves over two orbital p. Chemical bond in acetylene
( ethyne) consisted of overlap sp-sp between two carbon atoms forms sigma bond,
and two addition pi bonds formed by overlap p-p. Every carbon also tying with
hydrogen with angular s-sp overlap 180°.
Hybrid orbital sp yields linear molecule A-B-C or A-B-C-D ( like BeCl2, HgBr2,
HCN, C2H2) in linear attributed to tying σ with angle of tying 180º. In HCN and C2H2,
besides at tying CN and CC is formed with hybridization sp two tying sets π because
type overlap π with parallel direction with tying σ, and as a result triple bond C≡N
and C≡C formed.
93
Picture 4. Bonding At Etuna
d. Other Hybridization
Besides above hybrid orbital, other hybrid orbital type entangling orbital of d
also important. As shown in Tabel this orbital 1 relates to forming various molecule
structures.
Tables 1 Hybridization and molecule structure
94
A set of orbital of hybridization dsp3 at phosphorus atom ( PCl5)
II.Complex Hybridization and Compound Geometry
Valence bond theory developed by pauling. Based on this theory coordination
compound formed from reaction of between acids Lewis ( central atom or ion) with
alkaline Lewis ( ligand) through coordination covalent bond between both. In having
central coordination compound or atom complex compound or ion is certain
coordination number.
a. Coordination Compound Geometry
95
Theoritical of VSEPR ( valence shell electron pair repulsion), outmost skin
electron couples of incentre atom a molecule will stay on course which is each other
berjauhan causing reject refuses between electron couples in each the tying
mimimal. Based on at this principle, hence coordination compound geometry in
general can be predicted based on the ligand amounts, be linear geometry, trigonal
planar, tetrahedral, bipiramida trigonal, and oktahedral for complex with
coordination number each 2, 3, 4, 5 and 6.
b. Distortion Jahn-teller
Distortion Jahn-Teller is deviation of complex geometry (from oktahedral
becomes tetragonal) which caused by existence of electron at orbital of d at his(its
central ion. In this case ligand viewed as negative charge, for the reason will get
jerk by electron (also haves negative charge) found on orbital d. Even though only
electrons at certain orbital which its(the jerks is effective so that distortion Jahn-
Teller is observed. At tables of following summarized distortion yielded by orbital
electrons of d at complex " oktahedral".
System Structure predicted Description
High spin
d1, d6
d2, d7
d3, d8
d4, d9
d5, d10
Low Spin
Distorsi tetragonal
Distorsi tetragonal
Is not distortion
Distortion tetragonal which is big
Is not distortion
Is not distortion
Distortion tetragonal which is big
Is not observed
Is not observed
Proven experimentally
Proven experimentally
Proven experimentally
Proven experimentally
Yields square complex
96
d6
d8
Coordination compound geometry with coordination number 2, 3, 4 and 6 passed to
table 2 hereunder.
Tables 2. Complex Compound Geometry with a few Coordination number
Coordination
number
Geometry Contoh
2 Linear [Ag(NH3)2]+, [Cu(CN)2]-
3 Flat triangle [HgCl3]-, [AgBr(PPh3)2]
4 Tetrahedral [FeCl4]2-, [Zn(NH3)4]2+
4 Square [Ni(CN)4]2-, [Pt(CN)4]2-
5 Trigonal
bipiramidal
[CuCl5]3-, [Fe(CO)5]
6 Octahedral [CoF6]3-, [Fe(CN)6]3-
Based On Valence bond theory, geometry from complex compound closely
related with orbital geometry from central atoms or ion applied in tying forming. If
paid attention example at above tables, seen that the compound geometry or
complex ion nothing that looks like orbital 3 geometry of p, or orbital 5 geometry d.
thereby inferential that in forming of coordination covalent bond of orbital using
central atom or ion of hibrida formed through hybridization process.
Hybridization is orbital forming process of hibrida with the same energy level
from orbital of atom which the type and energy level differs in. Number of orbital of
97
hibrida formed is equal to number of orbital of atom involving in hybridization.
Hereunder some example of orbital hybridizations of central atom or ion along with
orbital geometry of hibrida obtained:
Tables 3 Example Of Hybridizations In Complex Compound
Hibridisasi Involving Atomic
Orbital
Orbital Geometry
of Hibrida
Example
sp1 orbital s and 1
orbital p
Linear [Cu(CN)2]-,
[Ag(NH3)2]+
sp2 1 orbital s and 2
orbital p
Flat triangle [HgCl3]-,
[AgBr(PPH3)2]
sp3 1 orbital s and 3
orbital p
Tetrahedral [FeCl4]2-,
[Zn(NH3)4]2+
dsp2 1 orbital d 1
orbita s and 2
orbital p
Bujursangkar [Ni(CN)4]2-,
[Cu(NH3)4]2+
98
dsp3 or sp3d 1 orbital d 1
orbita s and 3
orbital p
trigonal
bipiramidal
[CuCl5]3-, [Fe(CO)5]
d2sp3 or sp3d2 2 orbital d 1
orbita s and 3
orbital p
oktahedral [CoF6]3-, [Fe(CN)6]3-
In explaining forming of tying at complex compound, orbital of hibrida from
central atom or ion is depicted with box, radian or line. Forming of tying entangles
some steps, covers promotion of electron; orbital forming of hibrida; and forming of
tying between metals with ligand through overlap between orbital of hibrida empty
metal orbitally ligand containing free electron pairs.
c. Ligand Strength
Every ligand has strength of certain field. Based on strength research of
ligand field is:
CN- > NO2- > NH3 > H2O > F- > OH- > Cl- > Br- > I-
Strength of magnetic field in molecule determined by whether there or is not
there electron which couple.
If all paired electronses hence will experience rejection in magnetic field,
called as diamagnetic
If there are electron that is is not is couple hence will experience withdrawal
by magnetic field, called as character paramagnetik. More and more many
electrons that is is not is couple more and more strong the paramagnetik
character
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d. Character Paramagnetik
Transition metal differs from metals from short period, because at ions
forming, this metal doesn't discharge all the electronic valencies. Transition metal
from length period that is first, forms ion by discharging two electrons from orbital
of 4s by leaving orbital of 3d which tidal complete. This electrons according to law
Hund is not the couple and spin at the oposite.
Because atom with electron is not couple have moment permanent magnet,
hence this transition metal compounds haves the character of paramagnetik mean
can be pulled by magnetic field. Paramagnetic susceptibilitl which is caused by
electron that is is not is couple shown by formula:
S is number of spins quanta. Because every electron has spin quanta ± ½ hence
n= number of electrons is not couple
At hybridization entangling orbital of d, there is two kinds of possibility that
hybridization. If in orbital hybridization of d entangled is orbital of d which beyond
skin from orbital of sulfur and p having hybridization, hence complex formed
100
conceived of external orbital complex, or orbital outer of complex. On the contrary,
if in hybridization entangled is orbital of d in orbital skin of sulfur and p having
hybridization, hence the complex is named orbital complex in or orbital inner of
complex. Generally orbital complex in more stably is compared to external orbital
complex, because energy involved in by orbital complex formation in smaller
compared to energy involving in external orbital complex formation. Hybridization
to orbital of d is residing in in orbital of sulfur and p is required smaller energy,
because the energy level not too far.
Example :
[Ni(CO)4]; has geometric structure of tetrahedral
Ni28 : [Ar] 3d8 4s2
: [Ar]
3d8 4s2 4p0
Electron at orbital of 4s experiences promotion to orbital of 3d, so that orbital
empty 4s and can experience hybridization orbitally 4p forms orbital of
hibrida sp3.
Ni28 : [Ar]
3d8 4s 4p
Orbital of hibrida sp3 which has been formed then applied for tying with 4
ligand CO which rendering is each is free electron pairs
101
hybridization sp3
hibridisasi d2sp3
[Ni(CO)4] : [Ar]
3d10 sp3
Because all paired electronses, hence compound haves the character of
diamagnetic
[Fe(CN)6]3-; has geometrical form oktahedral
Fe26 : [Ar] 3d6 4s2
Fe3+ : [Ar] 3d5 4s0
: [ Ar]
3d5 4s1 4p0
Two electron at orbital of d which initialy not couple are paired with other
electron of the orbital of d, so that orbital 2 of d which initialy occupied by
both the empty electrons and applicable to form orbital of hibridal d2sp3
Fe3+ : [Ar]
Because orbital of d applied in this hybridization comes from orbital of d is
residing in disebelah in orbital of sulfur and p, hence complex orbitally a kind
of this hibrida conceived of orbital complex in ( orbital inner of complex)
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[Fe(CN)6]3- : [Ar]
Orbital of hibrida d2sp3 formed filled by electron pairs free of ligand CN-
In complex there are one electrons that is is not is couple, so that complex
had the character of paramagnetik.
[Ni(CN)4]2-, has geometrical form segiempat planar
Ni28 : [Ar] 3d8 4s2
: [Ar]
3d8 4s2 4p0
Ni2+ : [Ar]
One of electron at orbital of d which is not is couple is paired with other
electron, so that one of orbital of empty d and applicable to form orbital of
hibrida dsp3
[Ni(CN4)]2- : [Ar]
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forms orbital of hibrida dsp3
All electrons in this complex couple so that complex had the character of
diamagnetic
Most of more opting complex of orbital complex configuraton in, because
energy required when hybridization to entangle orbital of d side in smaller
compared to energy needed to entangles orbital of outer d. Nevertheless, if it is
seen from measurement of the magnetic moment, some complexes simply stays in
external orbital complex form.
Question that is often emerges is " When electrons of the orbital of d central
ion paired and when is not paired?" in this case is paired or not of electrons is
depend on the experiment fact. If from experiment it is obtained that a compound
or complex ion haves the character of diamagnetic hence the central atom or ion
has orbital of d or other orbital has been loaded is full or has orbital of d or other
orbital which has not been loaded is full but all the electrons in a state of couple. In
explaining forming of coordination covalent bond between ligands with central atom
or ion is entangled excitation phase. This excitation tends to happened if the ligand
is strong ligand like CN-, however factor influencing excitation is not only ligand
type. Many other factors having an effect on between it is number of ligands,
central ion type or atom and the complex geometry.
Until around year of 1943 valence bond theories is the only theory applied by
the expert of inorganic chemistry in explaining geometry and magnetism of
complex compound nevertheless this theory has weakness, that is:
1. Cannot explain magnetism change symptom of complex compound
because temperature change.
2. Cannot explain colour or spektra complex compound
104
3. Cannot explain stability of complex compound
Limitation of the hibtidisation theory be cannot explain magnetism
character. Existence of weakness from valence bond theory enables using of other
theory of which can explain third of above fact. One of theory is crystal magnet field
theory.
III. Com
plex Compound Nomenclature
Nomenclature applied for complex ion to come from Inorganic Nomenclasture
Committes of International Union of Pure Applied Chemistry ( C-IUPAC). For name of
visible ligands at tables 4
Tables 4. Name Of Ligands
Ligands Name of Ligands
NH3 Amino / amin
H2O Aquo
CO Karbonil
NO Nitrosil
NH2-CH2-CH2-NH2 Etilen diamin (en)
Negative Ligands Name of Ligands
CN- Siano
105
F- Fluoro
Cl- Kloro
Br- Bromo
I- Iodo
OH- Hidrokso
SCN- Tiosiano
S2O32- Tiosulfato
SO42- Sulfato
CO32- Karbonato
NO2- Nitro
O2- okso
If there is ligand multiple that is conspecific or not of a kind, the numbers
expressed as prefix in, three, tetra, and so. For ligands which is difficult, for
example ethylen is amen ( shortened en), if the numbers multiple, called as with
prefix:
Ethylen bus amen for ( en)= 2
Tris ethylen amen for ( en)= 3
Tetrakis ethylen amen for ( en)=4
106
a. Complex Ion Haves Positif Charge
Giving of complex compound ion which haves positif charge originally is
mentioned name of its(the ligand is then is followed name of its(the metal atom
( central atom). Oxidation number from central atom is written with number romawi
in parenthesis.
Example:
[Ag(NH3)2]+ = ion diamin perak (1)
[Fe(NH3)6]3+ = ion keksamin besi (III)
[Fe(H2O)6]2+ = ion heksaquo besi (II)
If the ligand multiple hence ligand sequence is mentioned as according to initial
letter alphabet from ligand and followed name of its(the metal atom ( central atom)
Example:
[Fe(H2O)4Cl2]+ = ion tetraquo dikloro besi (III)
[Co(NH3)4(CN)Br]+ = ion tetraamin bromo siano kobalt (III)
b. Complex Ion Haves Negative Charge
107
Giving of name of complex ion which haves negative charge, originally is
called as name of the ligand is then is followed name of its central atom is added
with suffix at. The oxidation number is written down with number romawi in
parenthesis.
Example:
[Ag(CN)2]- = ion disiano argemtat (I)
[Fe(Cl)6]3- = ion heksakloro ferrat (III)
If the ligand multiple hence ligand sequence is mentioned as according to initial
letter alphabet from ligand and followed name of the metal atom ( central atom).
Example:
[Cr(H2O)2I4]- = ion diaquo tetraiodo kromat (III)
[Co(NH3)2(CN)4]2- = ion diamin tetrasiano kobatlat (II)
c. Neutral Complex Compound ( nonionic)
Giving of name of neutral complex ion equal to giving of name of complex ion
loading negative.
Example:
[Zn(H2O)2Br] = diaquo dibromo zinkat(III)
108
[Co(NH3)3(NO2)3] = triamin trinitro kobaltat (III)
d. Complex Salts
Giving of the name is originally is mentioned the cation is then is followed the
anion.
Example:
K4[Fe(CN)6] = kalium heksasiano ferrat (II)
Na3[Co(Br06] = natrium heksabromo kobaltat (III)
[Cu(NH3)4]SO4 = tetramin tembaga (II) sulfat
[Cr(NH3)5Cl]Cl2 = pentamin kloro krom (III) Klorida
109
CONCLUSION
One of theory applied to explain tying forming, geometry and magnetic of
complex compound is valence bond theory. Based on this orbital theory of atom or
or central ion before receiving electron pairs free of ligand will experience
hybridization. Hybridization is orbital forming of hibrida which the energy level is
same from orbital of atom that is conspecific and the energy level differs in. Orbital
of hibrida will be filled by free electron couples or electron π is coming from ligand.
Complex compound geometry formed is explicable based on hybridization involving
in orbital forming of the hibrida.
Magnetic from predictable complex compound based on whether there or is
not there electron that is is not couple at orbital of central atom or ion. If there is
electron which is not is couple hence complex compound had the character of
110
paramagnetik, and when there are no electron which is not is couple hence complex
compound had the character of diamagnetic.
REFERENCES
111
Chang, Raymond. 2003. Edition Core Concepts Base Chemistry Third Volume 1.
Jakarta : Erlangga
Effendi. 1998. Coordination Chemistry. Malang: FMIPA IKIP Malang
Effendi. 2003. The theory VSEPR and Molecule Polar. Malang: Bayu Media
Publishing.
Kachi, Ohno. 2004. Quantum Chemistry. Tokyo : Iwanami Shoten Publishers
Yashito, Takeuchi. Chemical Deliverer Online Textbook. Tokyo : Iwanami Shoten
Publisher
http:// www.chem-is-try.org /hibridisasi-situs kimia
http:// www. chwm-is-try.org/ valence bond theory
http://www.chem-is-try.org/ orbital hybridization
http://www.chem-is-try.org//complex compound
http:// suyantakimiafmipaugm.wordpress.com /2010/05/17/bab-iii-stereokoimia-
senyawa-kompleks/
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Preliminary
Alkali metal
The alkali metals are a series of chemical elements forming Group 1 (IUPAC style) of the periodic table: lithium (Li), sodium (Na), potassium (K), rubidium (Rb), caesium (Cs), and francium (Fr). (Hydrogen, although nominally also a member of Group 1, very rarely exhibits behavior comparable to the alkali metals). The alkali metals provide one of the best examples of group trends in properties in the periodic table, with well characterized homologous behavior down the group.
Properties
The alkali metals are all highly reactive and are never found in elemental forms in nature. Because of this, they are usually stored immersed in mineral oil or kerosene (paraffin oil). They also tarnish easily and have low melting points and densities.
Physically, the alkali metals are mostly silver-colored, except for metallic caesium, which has a golden tint. These elements are all soft metals of low density. Chemically, all of the alkali metals react aggressively with the halogens to form ionic salts. They all react with water to form strongly alkaline hydroxides. The vigor of reaction increases down the group. All of the atoms of alkali metals have one electron in their outmost electron shells, hence their only way for achieving the equivalent of filled outmost electron shells is to give up one electron to an element with high electronegativity, and hence to become singly charged positive ions, i.e. cations.
When it comes to their nuclear physics, the elements potassium and rubidium are naturally weakly radioactive because they each contain a long half-life radioactive isotope.
The element hydrogen, with its solitary one electron per atom, is usually placed at the top of Group 1 of the periodic table for convenience, but hydrogen is not counted as an alkali metal. Under typical conditions, pure hydrogen exists as a diatomic gas consisting of two atoms per molecule.
The removal of the single electron of hydrogen requires considerably more energy than removal of the outer electron from the atoms of the alkali metals. As in the halogens, only one additional electron is required to fill in
113
the outermost shell of the hydrogen atom, so hydrogen can in some circumstances behave like a halogen, forming the negative hydride ion. Binary compounds of hydrogen with the alkali metals and some transition metals have been produced in the laboratory, but these are only laboratory curiosities without much practical use. Under extremely high pressures and low temperatures, such as those found at the cores of the planets Jupiter and Saturn, hydrogen does become a metallic element, and it behaves like an alkali metal. (See metallic hydrogen.)
The alkali metals have the lowest ionization potentials in their periods of the periodic table, because the removal of their single electrons from their outmost electron shells gives them the stable electron configuration of inert gases. Another way of stating this is that they all have a high electropositivity. The "second ionization potential" of all of the alkali metals is very high, since removing any electron from an atom having a noble gas configuration is difficult to do.
Series of alkali metals, stored in mineral oil ("natrium" is sodium.)
All of the alkali metals are notable for their vigorous reactions with water, and these reactions become increasingly vigorous when going down their column in the periodic table towards the heaviest alkali metals, such as caesium. Their chemical reactions with water are as follows:
Alkali metal + water → Alkali metal hydroxide + hydrogen gas
For a typical example (M represents an alkali metal):
2 M (s) + 2 H2O (l) → 2 MOH (aq) + H2 (g)
Trends
Like in other columns of the periodic table, the members of the alkali metal family show patterns in their electron configurations, especially their outmost electron shells. This causes similar patterns in their chemical properties:
114
ZElement
No. of electrons/shell
1Hydrogen
1
3 Lithium 2, 1
11 Sodium 2, 8, 1
19Potassium
2, 8, 8, 1
37Rubidium
2, 8, 18, 8, 1
55 Caesium 2, 8, 18, 18, 8, 1
87Francium
2, 8, 18, 32, 18, 8, 1
The alkali metals show a number of trends when moving down the group - for instance: decreasing electronegativity, increasing reactivity, and decreasing melting and boiling point. Their densities generally increase, with the notable exception that potassium is less dense than sodium, and the possible exception of francium being less dense than caesium. (The highly radioactive element francium only exists in microscopic quantities.)
Alkali metal
Standard atomic weight (u)
Melting point (K)
Boiling point (K)
Density (g·cm−3)
Electronegativity (Pauling)
Lithium 6.941 453 1615 0.534 0.98Sodium 22.990 370 1156 0.968 0.93Potassium 39.098 336 1032 0.89 0.82Rubidium 85.468 312 961 1.532 0.82Caesium 132.905 301 944 1.93 0.79Francium (223) 295 950 1.87 0.70
Group IB element
IUPAC has not recommended a specific format for the periodic table, so different conventions are permitted and are often used for group IB. The following d-block transition metals are always considered members of group IB:
115
scandium (Sc) yttrium (Y)
When defining the remainder of Group IB, four different conventions may be encountered:
Some tables [1] include lanthanum (La) and actinium (Ac), (the beginnings of the lanthanide and actinide series of elements, respectively) as the remaining members of Group IB. In their most commonly encountered tripositive ion forms, these elements do not possess any partially filled f orbitals, thus resulting in more d-block-like behavior.
Some tables [2] include lutetium (Lu) and lawrencium (Lr) as the remaining members of Group IB. These elements terminate the lanthanide and actinide series, respectively. Since the f-shell is nominally full in the ground state electron configuration for both of these metals, they behave most like d-block metals out of all the lanthanides and actinides, and thus exhibit the most similarities in properties with Sc and Y. For Lr, this behavior is expected, but it has not been observed because sufficient quantities are not available. (See also Periodic table (wide) and Periodic table (extended).)
Some tables [3] refer to all lanthanides and actinides by a marker in Group IB. A third and fourth alternative are suggested by this arrangement:
The third alternative is to regard all 30 lanthanide and actinide elements as included in Group IB. Lanthanides, as electropositive trivalent metals, all have a closely related chemistry, and all show many similarities to Sc and Y.
The fourth alternative is to include none of the lanthanides and actinides in Group IB. The lanthanides possess additional properties characteristic of their partially-filled f orbitals which are not common to Sc and Y. Furthermore, the actinides show a much wider variety of chemistry (for instance, in range of oxidation states) within their series than the lanthanides, and comparisons to Sc and Y are even less useful.
116
Elements of group IA
Hydrogen
Hydrogen is the lightest element. It is by far the most abundant element in the universe and makes up about about 90% of the universe by weight. Hydrogen as water (H2O) is absolutely essential to life and it is present in all organic compounds. Hydrogen is the lightest gas. Hydrogen gas was used in lighter-than-air balloons for transport but is far too dangerous because of the fire risk (Hindenburg). It burns in air to form only water as waste product and if hydrogen could be made on sufficient scale from other than fossil fuels then there might be a possibility of a hydrogen economy.
Note that while normally shown at the top of the Group 1 elements in the periodic table, the term "alkaline metal" refers only to Group 1 elements from lithium onwards.
Table: basic information about and classifications of hydrogen. Name : Hydrogen
Symbol : H
Atomic number : 1
Atomic weight : 1.00794 (7) [see notes g m r]
Standard state : gas at 298 K
CAS Registry ID : 1333-74-0
Group in periodic table : 1
Group name : (none)
Period in periodic table : 1
Block in periodic table : s-block
Colour : colourless
Classification : Non-metallic
117
The lifting agent for the ill fated Hindenberg ballooon was hydrogen rather than the safer helium. The image below is the scene probably in a way you have not seen it before. This is a "ray-traced" image reproduced with the permission of Johannes Ewers, the artist, who won first place with this image in the March/April 1999 Internet Raytracing Competition. For details of ray-tracing you can't beat the POV-Ray site.
Isolation
Isolation: in the laboratory, small amounts of hydrogen gas may be made by the reaction of calcium hydride with water.
CaH2 + 2H2O → Ca(OH)2 + 2H2
This is quite efficient in the sense that 50% of the hydrogen produced comes from water. Another very convenient laboratory scale experiment follows Boyle's early synthesis, the reaction of iron filings with dilute sulphuric acid.
Fe + H2SO4 → FeSO4 + H2
There are many industrial methods for the production of hydrogen and that used will depend upon local factors such as the quantity required and the raw materials to hand. Two processes in use involve heating coke with steam in the water gas shift reaction or hydrocarbons such as methane with steam.
CH4 + H2O (1100°C) → CO + 3H2
C(coke) + H2O (1000°C) → CO + H2
In both these cases, further hydrogen may be made by passing the CO and steam over hot (400°C) iron oxide or cobalt oxide.
CO + H2O → CO2 + H2
Table: valence shell orbital radii for hydrogen.
Orbital Radius [/pm] Radius [/AU]
s orbital 52.9 1.00003
p orbital no data no data
d orbital no data no data
f orbital no data no data
118
Effective Nuclear Charges
The following are "Clementi-Raimondi" effective nuclear charges, Zeff. Follow the hyperlinks for more details and for graphs in various formats.
Table: effective nuclear charges for hydrogen
1s no data
2s no data 2p no data
3s no data 3p no data 3d no data
4s no data 4p no data 4d no data 4f no data
5s no data 5p no data 5d no data
6s no data 6p no data
7s
119
Electron binding energies
This table contains electron binding energies for hydrogen.
Label Orbital eV [literature reference]
K 1s 13.6 [1]
120
Notes
All values of electron binding energies are given in eV. The binding energies are quoted relative to the vacuum level for rare gases and H2, N2, O2, F2, and Cl2 molecules; relative to the Fermi level for metals; and relative to the top of the valence band for semiconductors.
Lithium
Lithium is a Group 1 (IA) element containing just a single valence electron (1s22s1). Group 1 elements are called "alkali metals". Lithium is a solid only about half as dense as water and lithium metal is the least dense metal. A freshly cut chunk of lithium is silvery, but tarnishes in a minute or so in air to give a grey surface. Its chemistry is dominated by its tendency to lose an electron to form Li+. It is the first element within the second period.
Lithium is mixed (alloyed) with aluminium and magnesium for light-weight alloys, and is also used in batteries, some greases, some glasses, and in medicine.
Table: basic information about and classifications of lithium. Name : Lithium
Symbol : Li
Group in periodic table : 1
Group name : Alkali metal
121
Atomic number : 3
Atomic weight : [ 6.941 (2)] [see notes g m r]
Standard state : solid at 298 K
CAS Registry ID : 7439-93-2
Period in periodic table : 2
Block in periodic table : s-block
Colour : silvery white/grey
Classification : Metallic
Isolation
Isolation: lithium would not normally be made in the laboratory as it is so readily available commercially. All syntheses require an electrolytic step as it is so difficult to add an electron to the poorly electronegative lithium ion Li+.
The ore spodumene, LiAl(SiO3)2, is the most important commercial ore containing lithium. The α form is first converted into the softer β form by heating to around 1100°C. This is mixed carefully with hot sulphuric acid and extracted into water to form lithium sulphate, Li2SO4, solution. The sulphate is washed with sodium carbonate, Na2CO3, to form a precipitate of the relatively insoluble lithium carbonate, Li2CO3.
Li2SO4 + Na2CO3 → Na2SO4 + Li2CO3 (solid)
Reaction of lithium carbonate with HCl then provides lithium chloride, LiCl.
Li2CO3 + 2HCl → 2LiCl + CO2 +H2O
Lithium chloride has a high melting point (> 600°C) meaning that it sould be expensive to melt it in order to carry out the electrolysis. However a mixture of LiCl (55%) and KCl (45%) melts at about 430°C and so much less energy and so expense is required for the electrolysis.
cathode: Li+(l) + e- → Li (l)anode: Cl-(l) → 1/2Cl2 (g) + e-
Table: valence shell orbital radii for lithium.
122
Orbital Radius [/pm] Radius [/AU]
s orbital 164.1 3.10010
p orbital no data no data
d orbital no data no data
f orbital no data no data
Effective Nuclear Charges
The following are "Clementi-Raimondi" effective nuclear charges, Zeff. Follow the hyperlinks for more details and for graphs in various formats.
Table: effective nuclear charges for lithium
1s 2.69
2s 1.28 2p no data
3s no data 3p no data 3d no data
4s no data 4p no data 4d no data 4f no data
5s no data 5p no data 5d no data
6s no data 6p no data
7s
Electron binding energies
This table contains electron binding energies for lithium.
Label Orbital eV [literature reference]
K 1s 54.7 [2]
Sodium
123
Sodium is a Group 1 element (or IA in older labelling styles). Group 1 elements are often referred to as the "alkali metals". The chemistry of sodium is dominated by the +1 ion Na+. Sodium salts impart a characteristic orange/yellow colour to flames and orange street lighting is orange because of the presence of sodium in the lamp.
Soap is generally a sodium salt of fatty acids. The importance of common salt to animal nutrition has been recognized since prehistoric times. The most common compound is sodium chloride, (table salt).
Table: basic information about and classifications of sodium. Name : Sodium
Symbol : Na
Atomic number : 11
Atomic weight : 22.98976928 (2)
Standard state : solid at 298 K
CAS Registry ID : 7440-23-5
Group in periodic table : 1
Group name : Alkali metal
Period in periodic table : 3
Block in periodic table : s-block
Colour : silvery white
Classification : Metallic
The result of adding different metal salts to a burning reaction mixture of potassium chlorate and sucrose. The red colour originates from strontium sulphate. The orange/yellow colour originates from sodium chloride. The green colour originates from barium chlorate and the blue colour originates from copper (I) chloride. The lilac colour that should be evident from the potassium chlorate is washed out by the other colours, all of which are more intense (only to be demonstrated by a professionally qualified chemist following a legally satisfactory hazard asessment). Improperly done, this reaction is dangerous!
124
The picture above shows the colour arising from adding common salt (NaCl) to a burning mixture of potassium chlorate and sucrose.
Isolation
Isolation: sodium would not normally be made in the laboratory as it is so readily available commercially. All syntheses require an electrolytic step as it is so difficult to add an electron to the poorly electronegative sodium ion Na+.
Sodium is present as salt (sodium chloride, NaCl) in huge quantities in underground deposits (salt mines) and seawater and other natural waters. It is easily recovered as a solid by drying.
Sodium chloride has a high melting point (> 800°C) meaning that it sould be expensive to melt it in order to carry out the electrolysis. However a mixture of NaCl (40%) and calcium chloride, CaCl2 (60%) melts at about 580°C and so much less energy and so expense is required for the electrolysis.
cathode: Na+(l) + e- → Na (l)
anode: Cl-(l) → 1/2Cl2 (g) + e-
The electrolysis is carried out as a melt in a "Downs cell". In practice, the electrolysis process produces calcium metal as well but this is solidified in a collection pipe and returned back to the melt.
Table: valence shell orbital radii for sodium.Orbital Radius [/pm] Radius [/AU]
s orbital 179.4 3.39059
p orbital no data no data
d orbital no data no data
125
f orbital no data no data
Effective Nuclear Charges
The following are "Clementi-Raimondi" effective nuclear charges, Zeff. Follow the hyperlinks for more details and for graphs in various formats.
Table: effective nuclear charges for sodium
1s 10.63
2s 6.57 2p 6.80
3s 2.51 3p no data 3d no data
4s no data 4p no data 4d no data 4f no data
5s no data 5p no data 5d no data
6s no data 6p no data
7s
Electron binding energies
This table contains electron binding energies for sodium.
Label Orbital eV [literature reference]
K 1s 1070.8 [3]
L I 2s 63.5 [3]
L II 2p1/2 30.4 [3]
L III 2p3/2 30.5 [2]
Potassium
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Potassium is a metal and is the seventh most abundant and makes up about 1.5 % by weight of the earth's crust. Potassium is an essential constituent for plant growth and it is found in most soils. It is also a vital element in the human diet.
Potassium is never found free in nature, but is obtained by electrolysis of the chloride or hydroxide, much in the same manner as prepared by Davy. It is one of the most reactive and electropositive of metals and, apart from lithium, it is the least dense known metal. It is soft and easily cut with a knife. It is silvery in appearance immediately after a fresh surface is exposed.
It oxidises very rapidly in air and must be stored under argon or under a suitable mineral oil. As do all the other metals of the alkali group, it decomposes in water with the evolution of hydrogen. It usually catches fire during the reaction with water. Potassium and its salts impart a lilac colour to flames.
Table: basic information about and classifications of potassium. Name : Potassium
Symbol : K
Atomic number : 19
Atomic weight : 39.0983 (1)
Standard state : solid at 298 K
CAS Registry ID : 7440-09-7
Group in periodic table : 1
Group name : Alkali metal
Period in periodic table : 4
Block in periodic table : s-block
Colour : silvery white
Classification : Metallic
The reaction between potassium metal and water (only to be demonstrated by a professionally qualified chemist).
127
The picture above shows the colour arising from a burning mixture of potassium chlorate (KClO3) and sucrose (only to be demonstrated by a professionally qualified chemist).Isolation
Isolation: potassium would not normally be made in the laboratory as it is so readily available commercially. All syntheses require an electrolytic step as it is so difficult to add an electron to the poorly electronegative potassium ion K+.
Potassium is not made by the same method as sodium as might have been expected. This is because the potassium metal, once formed by electrolysis of liquid potassium chloride (KCl), is too soluble in the molten salt.
cathode: K+(l) + e- → K (l)
anode: Cl-(l) → 1/2Cl2 (g) + e-
Instead, it is made by the reaction of metallic sodium with molten potassium chloride at 850°C.
Na + KCl ⇌ K + NaCl
This is an equilibrium reaction and under these conditions the potassium is highly volatile and removed from the system in a form relatively free from sodium impurities, allowing the reaction to proceed.
Table: valence shell orbital radii for potassium.Orbital Radius [/pm] Radius [/AU]
s orbital 230.0 4.34528
p orbital no data no data
d orbital no data no data
128
f orbital no data no data
Effective Nuclear Charges
The following are "Clementi-Raimondi" effective nuclear charges, Zeff. Follow the hyperlinks for more details and for graphs in various formats.
Table: effective nuclear charges for potassium
1s 18.49
2s 13.01 2p 15.03
3s 8.68 3p 7.73 3d no data
4s 3.50 4p no data 4d no data 4f no data
5s no data 5p no data 5d no data
6s no data 6p no data
7s
Electron binding energies
This table contains electron binding energies for potassium.
Label Orbital eV [literature reference]
K 1s 3608.4 [2]
L I 2s 378.6 [2]
L II 2p1/2 297.3 [2]
L III 2p3/2 294.6 [2]
M I 3s 34.8 [2]
M II 3p1/2 18.3 [2]
M III 3p3/2 18.3 [2]
129
Rubidium
Rubidium can be liquid at ambient temperature, but only on a hot day given that its melting point is about 40°C. It is a soft, silvery-white metallic element of the alkali metals group (Group 1). It is one of the most most electropositive and alkaline elements. It ignites spontaneously in air and reacts violently with water, setting fire to the liberated hydrogen. As so with all the other alkali metals, it forms amalgams with mercury. It alloys with gold, caesium, sodium, and potassium. It colours a flame yellowish-violet.
Table: basic information about and classifications of rubidium. Name : Rubidium
Symbol : Rb
Atomic number : 37
Atomic weight : 85.4678 (3) [see note g]
Standard state : solid at 298 K
CAS Registry ID : 7440-17-7
Group in periodic table : 1
Group name : Alkali metal
Period in periodic table : 5
Block in periodic table : s-block
Colour : silvery white
Classification : Metallic
Image adapted with permission from Prof James Marshall's (U. North Texas, USA) Walking Tour of the elements CD.Isolation
Isolation: rubidium would not normally be made in the laboratory as it is available commercially. All syntheses require an electrolytic step as it is so difficult to add an electron to the poorly electronegative rubidium ion Rb+.
Rubidium is not made by the same method as sodium as might have been expected. This is because the rubidium metal, once formed by electrolysis of liquid rubidium chloride (RbCl), is too soluble in the molten salt.
130
cathode: Rb+(l) + e- → Rb (l)
anode: Cl-(l) → 1/2Cl2 (g) + e-
Instead, it is made by the reaction of metallic sodium with hot molten rubidium chloride.
Na + RbCl ⇌ Rb + NaCl
This is an equilibrium reaction and under these conditions the rubidium is highly volatile and removed from the system in a form relatively free from sodium impurities, allowing the reaction to proceed.
The following are calculated values of valence shell orbital radii, Rmax
Table: valence shell orbital radii for rubidium.
Orbital Radius [/pm] Radius [/AU]
s orbital 249.0 4.70616
p orbital no data no data
d orbital no data no data
f orbital no data no data
Effective Nuclear Charges
The following are "Clementi-Raimondi" effective nuclear charges, Zeff. Follow the hyperlinks for more details and for graphs in various formats.
Table: effective nuclear charges for rubidium
1s 36.21
2s 27.16 2p 33.04
3s 21.84 3p 21.30 3d 21.68
4s 12.39 4p 10.88 4d no data 4f no data
5s 4.98 5p no data 5d no data
6s no data 6p no data
131
7s
Electron binding energies
This table contains electron binding energies for rubidium.
Label Orbital eV [literature reference]
K 1s 15200 [1]
L I 2s 2065 [1]
L II 2p1/2 1864 [1]
L III 2p3/2 1804 [1]
M I 3s 326.7 [2]
M II 3p1/2 248.7 [2]
M III 3p3/2 239.1 [2]
M IV 3d3/2 113 [2]
M V 3d5/2 112 [2]
N I 4s 30.5 [2]
N II 4p1/2 16.3 [2]
N III 4p3/2 15.3 [2]
132
Caesium
Caesium is known as cesium in the USA. The metal is characterised by a spectrum containing two bright lines in the blue (accounting for its name). It is silvery gold, soft, and ductile. It is the most electropositive and most alkaline element. Caesium, gallium, and mercury are the only three metals that are liquid at or around room temperature. Caesium reacts explosively with cold water, and reacts with ice at temperatures above -116°C. Caesium hydroxide is a strong base and attacks glass.
Table: basic information about and classifications of caesium. Name : Caesium
Symbol : Cs
Atomic number : 55
Atomic weight : 132.9054519 (2)
Standard state : solid at 298 K (but melts only slightly above this temperature)
CAS Registry ID : 7440-46-2
Group in periodic table : 1
Group name : Alkali metal
Period in periodic table: 6
Block in periodic table : s-block
Colour : silvery gold
Classification : Metallic
Image adapted with permission from Prof James Marshall's (U. North Texas, USA) Walking Tour of the elements CD.Isolation
Isolation: caesium (cesium in USA) would not normally be made in the laboratory as it is available commercially. All syntheses require an electrolytic step as it is so difficult to add an electron to the poorly electronegative caesium ion Cs+.
Caesium is not made by the same method as sodium as might have been expected. This is because the caesium metal, once formed by electrolysis of liquid caesium chloride (CsCl), is too soluble in the molten salt.
133
cathode: Cs+(l) + e- → Cs (l)
anode: Cl-(l) → 1/2Cl2 (g) + e-
Instead, it is made by the reaction of metallic sodium with hot molten caesium chloride.
Na + CsCl ⇌ Cs + NaCl
This is an equilbrium reaction and under these conditions the caesium is highly volatile and removed from the system in a form relatively free from sodium impurities, allowing the reaction to proceed. It can be purified by distillation.
The following are calculated values of valence shell orbital radii, Rmax
Table: valence shell orbital radii for caesium.
Orbital Radius [/pm] Radius [/AU]
s orbital 282.4 5.33704
p orbital no data no data
d orbital no data no data
f orbital no data no data
Effective Nuclear Charges
The following are "Clementi-Raimondi" effective nuclear charges, Zeff. Follow the hyperlinks for more details and for graphs in various formats.
Table: effective nuclear charges for caesium
1s 53.90
2s 40.51 2p 50.82
3s 36.38 3p 36.58 3d 40.98
4s 27.04 4p 25.86 4d 22.84 4f no data
5s 15.44 5p 13.65 5d no data
6s 6.36 6p no data
134
7s
Electron binding energies
This table contains electron binding energies for caesium.
Label Orbital eV [literature reference]
K 1s 35985 [1]
L I 2s 5714 [1]
L II 2p1/2 5359 [1]
L III 2p3/2 5012 [1]
M I 3s 1211 [2, values derived from reference 1]
M II 3p1/2 1071 [2]
M III 3p3/2 1003 [2]
M IV 3d3/2 740.5 [2]
M V 3d5/2 726.6 [2]
N I 4s 232.3 [2]
N II 4p1/2 172.4 [2]
N III 4p3/2 161.3 [2]
N IV 4d3/2 79.8 [2]
N V 4d5/2 77.5 [2]
N VI 4f5/2 -
N VII 4f7/2 -
O I 5s 22.7
135
O II 5p1/2 14.2 [2]
O III 5p3/2 12.1 [2]
Francium
Francium occurs as a result of α disintegration of actinium. Francium is found in uranium minerals, and can be made artificially by bombarding thorium with protons. It is the most unstable of the first 101 elements. The longest lived isotope, 223Fr, a daughter of 227Ac, has a half-life of 22 minutes. This is the only isotope of francium occurring in nature, but at most there is only 20-30 g of the element present in the earth's crust at any one time. No weighable quantity of the element has been prepared or isolated. There are about 20 known isotopes.
Table: basic information about and classifications of francium. Name : Francium
Symbol : Fr
Atomic number : 87
Atomic weight : [ 223 ]
Standard state : solid at 298 K
CAS Registry ID : 7440-73-5
Group in periodic table : 1
Group name : Alkali metal
Period in periodic table : 7
Block in periodic table : s-block
Colour : metallic
Classification : Metallic
136
This sample of uraninite contains some francium because of a steady-state decay chain. An estimate suggests there is about 10-20
grammes of francium (about 1 atom!) at any one time. Image adapted with permission from Prof James Marshall's (U. North Texas, USA) Walking Tour of the elements CD.Isolation
Isolation: francium is vanishingly rare and is found only as very small traces in some uranium minerals. It has never been isolated as the pure element. As it is so radioactive, any amount formed would decompose to other elements.
Actinium decays by β decay most of the time but about 1% of the decay is by α decay. The "daughter" element of this reaction, which used to be called actinium-K, is now recognized as 223
87Fr - the longest-lived isotope of actinium with a half life of about 22 minutes.
The following are calculated values of valence shell orbital radii, Rmax
Table: valence shell orbital radii for francium.
Orbital Radius [/pm] Radius [/AU]
s orbital 298.6 5.64197
p orbital no data no data
d orbital no data no data
f orbital no data no data
Effective Nuclear Charges
137
The following are "Clementi-Raimondi" effective nuclear charges, Zeff. Follow the hyperlinks for more details and for graphs in various formats.
Table: effective nuclear charges for francium
1s no data
2s no data 2p no data
3s no data 3p no data 3d no data
4s no data 4p no data 4d no data 4f no data
5s no data 5p no data 5d no data
6s no data 6p no data
7s
Electron binding energies
This table contains electron binding energies for francium.
Label Orbital eV [literature reference]
K 1s 101137 [1]
L I 2s 18639 [1]
L II 2p1/2 17907 [1]
L III 2p3/2 15031 [1]
M I 3s 4652 [1]
M II 3p1/2 4327 [1]
M III 3p3/2 3663 [1]
M IV 3d3/2 3136 [1]
M V 3d5/2 3000 [1]
N I 4s 1153 [2]
N II 4p1/2 980 [2]
138
N III 4p3/2 810 [2]
N IV 4d3/2 603 [2]
N V 4d5/2 577 [2]
N VI 4f5/2 268 [2]
N VII 4f7/2 268 [2]
O I 5s 234 [2]
O II 5p1/2 182 [2]
O III 5p3/2 140 [2]
O IV 5d3/2 58 [2]
O V 5d5/2 58 [2]
P I 6s 34 [1]
P II 6p1/2 15 [1]
P III 6p3/2 15 [1]
Elements of group IB
Scandium
Scandium is a silvery-white metal which develops a slightly yellowish or pinkish cast upon exposure to air. It is relatively soft, and resembles yttrium and the rare-earth metals more than it resembles aluminium or titanium. Scandium reacts rapidly with many acids.
Scandium is apparently a much more abundant element in the sun and certain stars than on earth.
Table: basic information about and classifications of scandium.
139
Name : Scandium
Symbol : Sc
Atomic number : 21
Atomic weight : 44.955912 (6)
Standard state : solid at 298 K
CAS Registry ID : 7440-20-2
Group in periodic table : 3
Group name : (none)
Period in periodic table : 4
Block in periodic table : d-block
Colour : silvery white
Classification : Metallic
Image adapted with permission from Prof James Marshall's (U. North Texas, USA) Walking Tour of the elements CD.Isolation
Isolation: preparation of metallic samples of scandium is not normally necessary given that it is commercially avaialable. In practice littel scandium is produced. The mineral thortveitite contains 35-40% Sc2O3 is used to produce scandium metal but another important source is as a byproduct from uranium ore processing, even though these only contain 0.02% Sc2O3.
Brief description: yttrium has a silvery-metallic lustre. Yttrium turnings ignite in air. Yttrium is found in most rare-earth minerals. Moon rocks contain yttrium and yttrium is used as a "phosphor" to produce the red colour in television screens.
Scandium: orbital properties
Valence shell orbital radii
The following are calculated values of valence shell orbital radii, Rmax
Table: valence shell orbital radii for scandium.
140
Orbital Radius [/pm] Radius [/AU]
s orbital 171.6 3.24169
p orbital no data no data
d orbital 59.2 1.11908
f orbital no data no data
Effective Nuclear Charges
The following are "Clementi-Raimondi" effective nuclear charges, Zeff. Follow the hyperlinks for more details and for graphs in various formats.
Table: effective nuclear charges for scandium
1s 20.46
2s 14.57 2p 17.05
3s 10.34 3p 9.41 3d 7.12
4s 4.63 4p no data 4d no data 4f no data
5s no data 5p no data 5d no data
141
6s no data 6p no data
7s
Electron binding energies
This table contains electron binding energies for scandium.
Label Orbital eV [literature reference]
K 1s 4492 [1]
L I 2s 498 [2]
L II 2p1/2 403.6 [2]
L III 2p3/2 398.7 [2]
M I 3s 51.1 [2]
M II 3p1/2 28.3 [2]
M III 3p3/2 28.3 [2]
142
Yttrium
Table: basic information about and classifications of yttrium. Name : Yttrium
Symbol : Y
Atomic number : 39
Atomic weight : 88.90585 (2)
Standard state : solid at 298 K
CAS Registry ID : 7440-65-5
Group in periodic table : 3
Group name : (none)
Period in periodic table : 5
Block in periodic table : d-block
Colour : silvery white
Classification : Metallic
143
This sample is from The Elements Collection, an attractive and safely packaged collection of the 92 naturally occurring elements that is available for sale.Isolation
Isolation: yttrium metal is available commercially so it is not normally necesary to make it in the laboratory. Yttrium is found in lathanoid minerals and the extraction of the yttrium and the lanthanoid metals from the ores is highly complex. Initially, the metals are extractedas salts from the ores by extraction with sulphuric acid (H2SO4), hydrochloric acid (HCl), and sodium hydroxide (NaOH). Modern purification techniques for these lanthanoid salt mixtures involve selective complexation techniques, solvent extractions, and ion exchange chromatography.
Pure yttrium is available through the reduction of YF3 with calcium metal.
2YF3 + 3Ca → 2Y + 3CaF2
Yttrium: orbital properties
Valence shell orbital radii
The following are calculated values of valence shell orbital radii, Rmax
Table: valence shell orbital radii for yttrium.Orbital Radius [/pm] Radius [/AU]
s orbital 189.1 3.57338
p orbital no data no data
d orbital 93.9 1.77384
144
f orbital no data no data
Effective Nuclear Charges
The following are "Clementi-Raimondi" effective nuclear charges, Zeff. Follow the hyperlinks for more details and for graphs in various formats.
Table: effective nuclear charges for yttrium
1s 38.18
2s 28.62 2p 35.00
3s 23.55 3p 23.09 3d 25.40
4s 14.26 4p 12.75 4d 15.96 4f no data
5s 6.26 5p no data 5d no data
6s no data 6p no data
7s
Electron binding energies
This table contains electron binding energies for yttrium.
Label Orbital eV [literature reference]
K 1s 17038 [1]
L I 2s 2373 [1]
L II 2p1/2 2156 [1]
L III 2p3/2 2080 [1]
M I 3s 392 [2, values derived from reference 1]
M II 3p1/2 310.6 [2]
M III 3p3/2 298.8 [2]
M IV 3d3/2 157.7 [3]
145
M V 3d5/2 155.8 [3]
N I 4s 43.8 [2]
N II 4p1/2 24.4 [2]
N III 4p3/2 23.1 [2]
Lutetium
Lutetium: the essentials
Brief description: pure metal lutetium has been isolated only in recent years and is one of the more difficult to prepare. It can be prepared by the reduction of anhydrous LuCl3 or LuF3 by an alkali or alkaline earth metal.
The metal is silvery white and relatively stable in air. It is a rare earth metal and perhaps the most expensive of all rare elements. It is found in small amounts with all rare earth metals, and is very difficult to separate from other rare elements.
Table: basic information about and classifications of lutetium. Name : Lutetium
Symbol : Lu
Atomic number : 71
Atomic weight : 174.9668 (1) [see note g]
Standard state : solid at 298 K
CAS Registry ID : 7439-94-3
Group in periodic table : 3
Group name : (none)
Period in periodic table : 6
Block in periodic table : d-block
Colour : silvery white
Classification : Metallic
146
This sample is from The Elements Collection, an attractive and safely packaged collection of the 92 naturally occurring elements that is available for sale.Isolation
Isolation: lutetium metal is available commercially so it is not normally necessary to make it in the laboratory, which is just as well as it is difficult to isolate as the pure metal. This is largely because of the way it is found in nature. The lanthanoids are found in nature in a number of minerals. The most important are xenotime, monazite, and bastnaesite. The first two are orthophosphate minerals LnPO4 (Ln deonotes a mixture of all the lanthanoids except promethium which is vanishingly rare) and the third is a fluoride carbonate LnCO3F. Lanthanoids with even atomic numbers are more common. The most comon lanthanoids in these minerals are, in order, cerium, lanthanum, neodymium, and praseodymium. Monazite also contains thorium and ytrrium which makes handling difficult since thorium and its decomposition products are radioactive.
For many purposes it is not particularly necessary to separate the metals, but if separation into individual metals is required, the process is complex. Initially, the metals are extracted as salts from the ores by extraction with sulphuric acid (H2SO4), hydrochloric acid (HCl), and sodium hydroxide (NaOH). Modern purification techniques for these lanthanoid salt mixtures are ingenious and involve selective complexation techniques, solvent extractions, and ion exchange chromatography.
Pure lutetium is available through the reduction of LuF3 with calcium metal.
2LuF3 + 3Ca → 2Lu + 3CaF2
This would work for the other calcium halides as well but the product CaF2 is easier to handle under the reaction conditions (heat to 50°C above the melting point of the element in an argon atmosphere). Excess calcium is removed from the reaction mixture under vacuum.
147
Lutetium: orbital properties
Valence shell orbital radii
The following are calculated values of valence shell orbital radii, Rmax
Table: valence shell orbital radii for lutetium.
Orbital Radius [/pm] Radius [/AU]
s orbital 186.7 3.52829
p orbital no data no data
d orbital 95.0 1.79586
f orbital 24.6 0.465285
Effective Nuclear Charges
The following are "Clementi-Raimondi" effective nuclear charges, Zeff. Follow the hyperlinks for more details and for graphs in various formats.
Table: effective nuclear charges for lutetium
1s 69.62
2s 52.45 2p 66.61
3s 49.53 3p 50.17 3d 57.42
4s 38.27 4p 37.19 4d 35.29 4f 30.93
5s 20.96 5p 18.68 5d 20.11
6s 8.80 6p no data
7s
Electron binding energies
This table contains electron binding energies for lutetium.
Label Orbital eV [literature reference]
148
K 1s 63314 [1]
L I 2s 10870 [1]
L II 2p1/2 10349 [1]
L III 2p3/2 9244 [1]
M I 3s 2491 [1]
M II 3p1/2 2264 [1]
M III 3p3/2 2024 [1]
M IV 3d3/2 1639 [1]
M V 3d5/2 1589 [1]
N I 4s 506.8 [2]
N II 4p1/2 412.4 [2]
N III 4p3/2 359.2 [2]
N IV 4d3/2 206.1 [2]
N V 4d5/2 196.3 [2]
N VI 4f5/2 8.9 [2]
N VII 4f7/2 7.5 [2]
O I 5s 57.3 [2]
O II 5p1/2 33.6 [2]
O III 5p3/2 26.7 [2]
Lawrencium
Lawrencium: the essentials
149
Brief description: lawrencium is a synthetic "rare earth metal" which does not occur in the environment.
Table: basic information about and classifications of lawrencium. Name : Lawrencium
Symbol : Lr
Atomic number : 103
Atomic weight : [ 262 ]
Standard state : presumably a solid at 298 K
CAS Registry ID : 22537-19-5
Group in periodic table : 3
Group name : (none)
Period in periodic table : 7
Block in periodic table : d-block
Colour : unknown, but probably metallic and silvery white or grey in appearance
Classification : Metallic
Lawrencium: orbital properties
Valence shell orbital radii
The following are calculated values of valence shell orbital radii, Rmax
Table: valence shell orbital radii for lawrencium.
Orbital Radius [/pm] Radius [/AU]
s orbital 203.1 3.83753
p orbital no data no data
d orbital 104.0 1.96493
f orbital 38.9 0.735260
Effective Nuclear Charges
The following are "Clementi-Raimondi" effective nuclear charges, Zeff. Follow the hyperlinks for more details and for graphs in various formats.
Table: effective nuclear charges for lawrencium
150
1s no data
2s no data 2p no data
3s no data 3p no data 3d no data
4s no data 4p no data 4d no data 4f no data
5s no data 5p no data 5d no data
6s no data 6p no data
7s
Reference
151
1. D.R. Lide, (Ed.) in Chemical Rubber Company handbook of chemistry and physics, CRC Press, Boca Raton, Florida, USA, 81st edition, 2000.
2. E. Clementi and D.L.Raimondi, J. Chem. Phys. 1963, 38, 2686.
3. E. Clementi, D.L.Raimondi, and W.P. Reinhardt, J. Chem. Phys. 1967, 47, 1300.
4. J. A. Bearden and A. F. Burr, "Reevaluation of X-Ray Atomic Energy Levels," Rev. Mod. Phys., 1967, 39, 125.
5. J.B. Mann, Atomic Structure Calculations II. Hartree-Fock wave functions and radial expectation values: hydrogen to lawrencium, LA-3691, Los Alamos Scientific Laboratory, USA, 1968.
6. J. C. Fuggle and N. Mårtensson, "Core-Level Binding Energies in Metals," J. Electron Spectrosc. Relat. Phenom., 1980, 21, 275.
7. Gwyn Williams WWW table of values
8. M. Cardona and L. Ley, Eds., Photoemission in Solids I: General Principles (Springer-Verlag, Berlin) with additional corrections, 1978.
152
CHAPTER I
IIA ELEMENTS
Some of the physical properties usually associated with metals—hardness,
high m.p. and b.p.—are noticeably lacking in these metals, but they all have
a metallic appearance and are good electrical conductors. Group II metals
are more dense, are harder and have higher m.p. and b.p. than the
corresponding Group I metals. bonding generally depends on the ratio
(number of electrons available for bonding)/(atomic size). The greater this
ratio is, the stronger are the bonds between the metal atoms. In the pre-
transition metals, this ratio is small and at a minimum in Group I with only
one bonding electron. Metallic bond strength is greater in Group II but there
are still only two bonding electrons available, hence the metals are still
relatively soft and have low melting and boiling points. Hardness, m.p. and
b.p. all decrease steadily down Group I, the metallic bond strength
decreasing with increasing atomic radius. These changes are not so well
marked in Group II but note that beryllium and, to a lesser extent,
magnesium are hard metals, as a result of their small atomic size; this
property, when coupled with their low density, makes them of some
technological importance.
Group II (alkaline earths) are known as s-block elements because their
valence (bonding) electrons are in s orbitals.
PHYSICAL PROPERTIES OF IIA ELEMENTS
Element Atomic
number
Outer
electrons
Density
(g/ )
m.p.
(K)
b.p.
(K)
Hardness
(Brinell)
Be
Mg
Ca
Sr
Ba
4
12
20
38
56
2
3
4
5
1.86
1.75
1.55
2.6
3.59
1553
924
1124
1073
998
3243
1380
1760
1639
1910
-
30-40
23
20.
-
153
6
Element lonisatio
n
energy*
(kJ/mol)
Metallic
radius
(nm)
Ionic
radius
(nm)
Heat of
vaporisatio
n
at 298 K
(kJ/mol)
Hydrat ion
energy of
gaseous ion
(kJ/mol)
Be
Mg
Ca
Sr
Ba
2657
2187
1735
1613
1467
0.112
0.160
0.197
0.215
0.221
0.031
0.065
0.099
0.113
0.135
326
149
177
164
178
2494
1921
1577
1443
1305
Atomic Radius Increases down each group electrons are in shells further
from the nucleus
Ionic Size Increases down the group The size of positive ions is less than
the original atom because the nuclear charge exceeds the electronic charge.
Melting Points Decrease down each group metallic bonding gets weaker
due to increased size
Each atom contributes two electrons to the delocalised cloud. Melting points
tend
not to give a decent trend as different crystalline structures affect the melting
point.
CHEMICAL PROPERTIES OF THE ELEMENTSOverall Reactivity increases down the Group due to the ease of cation formation
Oxygen • react with increasing vigour down the groupWater • react with increasing vigour down the group
154
OXIDES OF GROUP II ELEMENTS
Properties • ionic solids; EXC. beryllium oxide which has covalent character
Hydroxides• basic strength also increases down group• this is because the solubility increases• the metal ions get larger so charge density decreases• there is a lower attraction between the OH¯ ions and larger dipositive ions• the ions will split away from each other more easily• there will be a greater concentration of OH¯ ions in water
Uses of hydroxides Ca(OH) • used in agriculture to neutralise acid soilsCARBONATES
Properties • insoluble in water• undergo thermal decomposition to oxide and carbon dioxide
We note first that the elements are all electropositive, having relatively
low ionisation energies, and are, in consequence, very reactive. The enthalpy
change required for the process M(metal) -»M + (g) for Group I, or M(metal) -
> M2+(g) for Group II is at a maximum at the top of each group, and it is,
therefore, not surprising
to find that lithium, beryllium and, to some extent, magnesium do form some
covalent compounds. Most solid compounds of Group 1 and II elements,
however, have ionic structures and the properties associated with such
structures—high m.p. and b.p., solubility in water rather than in organic
solvents and electrical conductance when molten.
IONS IN SOLUTION
The hydration energies (strictly, hydration enthalpies) fall, as expected, as
we descend either Group, and are larger for Group II than for Group I ions.
The solubilities of the salts of Groups I and II are determined by a balance
155
between lattice energy, hydration energy and the entropy change in going
from solid to solution, and
only a few generalisations are possible. Thus high charge and low ionic radii
tend to produce insolubility (for example salts of lithium, beryllium and
magnesium, especially those with doubly charged anions such as carbonate
COa~). At the other end of the scale, low charge and large radii also produce
low solubility (for example salts of potassium, rubidium and caesium
containing large anions such as the tetraphenylborate anion (p. 136). In
between, solubility is the rule for all Group I salts, and for most Group II salts
containing singly-charged negative ions; for many Group II salts with
doublyor triply-charged anions (for example COj", SOj", PO^ ) insolubility is
often observed. The decreasing tendency to form salts with water of
crystallization (as a group is descended) is again in line with the falling
hydration
energy. For example, both sodium sulphate and carbonate form hydrates but
neither of the corresponding potassium salts do; the sulphates of Group II
elements show a similar trend MgSO4 , 7H2O, CaSO4 . 2H2O, BaSO4. For the
most part, however, the chemistry of the Group I and II elements is that of
the metal and the ions M +
for Group I and M2* for Group II. As already noted the two head elements,
lithium and beryllium, tend to form covalent compounds; the beryllium ion
Be2 + , because of its very small radius and double charge, has also some
peculiar properties in solution, which are examined later
OCCURRENCE AND EXTRACTION
Of the Group II metals (beryllium to barium) beryllium, the rarest, occurs as
the aluminatesilicate, beryl \magnesium is found as the carbonate and (with
calcium) as the double carbonate dolomite', calcium, strontium and barium
all occur as carbonates, calcium carbonate being very plentiful as limestone.
The general characteristics of all these elements generally preclude their
extraction by any method involving aqueous solution. For the lighter, less
volatile metals (Li, Na, Be, Mg, Ca) electrolysis of a fused salt (usually the
156
chloride), or of a mixture of salts, is used. The heavier, more volatile metals
in each group can all be similarly obtained by electrolysis, but it is usually
more convenient to take advantage of their volatility and obtain them from
their oxides or chlorides by displacement, i.e. by general reactions such as
3M2O + 2Mm -* M2
mO3 4- 6M|
MCI + M1 ~» M!C1 + M|
Thus potassium is obtained by heating potassium chloride with sodium, and
barium by reduction of barium oxide with aluminium. Sodium is important in
many technical processes and is therefore prepared in considerable quantity.
Almost all of it is now made by electrolysis of the fused sodium chloride,
using the Downs cell. The graphite anode is cylindrical and is surrounded by
the steel gauze diaphragm and the concentric cylindrical cathode (also of
steel). The electrolyte is usually a mixture of sodium chloride and calcium
chloride; the latter is added to reduce the m.p. of the
sodium chloride to approximately 800 K. (Some calcium is therefore
liberated with the sodium.) The gap between anode and cathode is kept as
small as possible to reduce resistance: the heat developed by the current
maintains the temperature of the cell. Chlorine is set free at the anode
surface, rises into the nickel cone and can be collected. Sodium, liberated at
the cathode, is prevented by the diaphragm from passing into the anode
region; the molten sodium collects under the circular hood and rises up the
pipe, being assisted if necessary by the puddle-rod. The calcium, being
almost immiscible with sodium and much more dense, can readily be
separated from
the molten sodium. The graphite anode wears away and must be renewed
from time to time.
Element Be Mg Ca Sr Ba
Reaction Does not react with
Very slowl with water, readily
React with cold water. vigour of reaction increasing.
157
Conditions
Basic
properties
of product
with water,
Be(OH)2
amphoteric
with
steam
MgO
insoluble
Slightly soluble M soluble
Base strength increasing
USES
Beryllium is added to copper to produce an alloy with greatly increased wear
resistance; it is used for current-carrying springs and non-sparking safety
tools. It is also used as a neutron moderator and reflector in nuclear reactors.
Much magnesium is used to prepare light metal alloys; other uses include
the extraction of titanium and in the removal of oxygen and sulphur from
steels; calcium finds a similar use.
BIOLOGICAL IMPORTANCE
Sodium and potassium ions are found in all animal cells and, usually, the
concentration of potassium ions inside the cell is greater than that of sodium.
In many cells, this concentration difference is maintained by a 'sodium
pump', a process for which the energy is supplied by the hydrolysis of
adenosine triphosphate (ATP). Diffusion of excess potassium ions outwards
through the cell wall gives the inside of the cell a net negative charge (due
to the anions present) and a potential difference is established across the
cell wall. In a nerve cell, a momentary change in the permeability of the cell
wall to sodium ions can reverse the sign of this potential difference, and this
produces the electrical impulse associated with the action of the nerve.
158
The ability of living organisms to differentiate between the chemically similar
sodium and potassium ions must depend upon some difference between
these two ions in aqueous solution. Essentially, this difference is one of size
of the hydrated ions, which in turn means a difference in the force of
electrostatic (coulombic) attraction between the hydrated cation and a
negatively-charged site in the cell membrane; thus a site may be able to
accept the smaller ion Na+(aq) and reject the larger K+(aq). This same
mechanism of selectivity operates in other 'ion-selection' processes, notably
in ionexchange resins. All organisms seem to have an absolute need for
magnesium. In plants, the magnesium complex chlorophyll is the prime
agent in photosynthesis. In animals, magnesium functions as an enzyme
activator; the enzyme which catalyses the ATP hydrolysis mentioned above
is an important example. Calcium plays an important part in structure-
building in living organisms, perhaps mainly because of its ability to link
together phosphate-containing materials. Calcium ions in the cell play a vital
part in muscle contraction.
THE HYDRIDES
All Group I and II elements, except beryllium, form hydrides by direct
combination with hydrogen. The hydrides of the metals except those of
beryllium and magnesium, are white mainly ionic solids, all Group I hydrides
having the sodium chloride lattice
structure. All the hydrides are stable in dry air but react with water, the
vigour of the reaction increasing with the molecular weight of the hydride for
any particular group.
Group II metals also form halides by direct combination. The trends in heat of
formation and m.p., however, whilst following the general pattern of the
corresponding Group I compounds, are not so regular.
* Lithium bromide and iodide probably have some degree of covalency but
this
does not affect the general conclusion.
159
As a consequence of the high ionisation energy of beryllium its halides are
essentially covalent, with comparatively low m.p., the melts being non-
conducting and (except beryllium fluoride) dissolving in many organic
solvents. The lower members in Group II form essentially ionic halides, with
magnesium having intermediate properties, and both magnesium bromide
and iodide dissolve in organic solvents. The lattice energies of the Group II
fluorides are generally greater than those for the corresponding Group I
fluorides; consequently all but beryllium fluoride are insoluble. (The solubility
of
beryllium fluoride is explained by the high hydration energy of the beryllium
ion, cf. LiF.) The high hydration energy of the Be2+ ion* results in hydrolysis
in neutral or alkaline aqueous solution; in this reaction the beryllium halides
closely resemble the aluminium halides.
The magnesium ion having a high hydration energy also shows hydrolysis
but to a lesser extent, The chloride forms several hydrates which decompose
on heating to give a basic salt. Other Group II halides are essentially ionic
and therefore have relatively high m.p., the melts acting as conductors, and
they are soluble in water but not in organic solvents.
a. Beryllium
Beryllium was discovered by Louis-Nicholas Vauquelin in 1798. Vauquelin
found beryllia (BeO) in emeralds and in the mineral beryl (beryllium
aluminum cyclosilicate). Beryllium was first isolated by Friederich Wöhler in
1828. Wöhler reacted potassium with beryllium chloride in a platinum
crucible yielding potassium chloride and beryllium.
Unlike most metals, beryllium is virtually transparent to x-rays and hence it
is used in radiation windows for x-ray tubes. Beryllium alloys are used in the
aerospace industry as light-weight materials for high performance aircraft,
satellites and spacecraft. Beryllium is also used in nuclear reactors as a
reflector and absorber of neutrons, a shield and a moderator.
160
Beryllium is used as an alloying agent in producing beryllium copper, which
is extensively used for springs, electrical contacts, spot-welding electrodes,
and non-sparking tools. It is applied as a structural material for high-speed
aircraft, missiles, spacecraft, and communication satellites. Other uses
include windshield frame, brake discs, support beams, and other structural
components of the space shuttle.
Because beryllium is relatively transparent to X-rays, ultra-thin Be-foil is
finding use in X-ray lithography for reproduction of micro-miniature
integrated circuits.
Beryllium is used in nuclear reactors as a reflector or moderator for it has a
low thermal neutron absorption cross section.
It is used in gyroscopes, computer parts, and instruments where lightness,
stiffness, and dimensional stability are required. The oxide has a very high
melting point and is also used in nuclear work and ceramic applications.
Beryllium is found in some 30 mineral species, the most important of which
are bertrandite, beryl, chrysoberyl, and phenacite. Aquamarine and emerald
are precious forms of beryl. Beryl and bertrandite are the most important
commercial sources of the element and its compounds. Most of the metal is
now prepared by reducing beryllium fluoride with magnesium metal.
Beryllium metal did not become readily available to industry until 1957.
The metal, steel gray in color, has many desirable properties. As one of the
lightest of all metals, it has one of the highest melting points of the light
metals. Its modulus of elasticity is about one third greater than that of steel.
It resists attack by concentrated nitric acid, has excellent thermal
conductivity, and is nonmagnetic. It has a high permeability to X-rays and
161
when bombarded by alpha particles, as from radium or polonium, neutrons
are produced in the amount of about 30 neutrons/million alpha particles.
At ordinary temperatures, beryllium resists oxidation in air, although its
ability to scratch glass is probably due to the formation of a thin layer of the
oxide.
Beryllium and its salts are toxic and should be handled with the greatest of
care. Beryllium and its compounds should not be tasted to verify the
sweetish nature of beryllium (as did early experimenters). The metal, its
alloys, and its salts can be handled if certain work codes are observed, but
no attempt should be made to work with beryllium before becoming familiar
with proper safeguards.
b. Magnesium
Although it is the eighth most abundant element in the universe and the
seventh most abundant element in the earth's crust, magnesium is never
found free in nature. Magnesium was first isolated by Sir Humphry Davy, an
English chemist, through the electrolysis of a mixture of magnesium oxide
(MgO) and mercuric oxide (HgO) in 1808. Today, magnesium can be
extracted from the minerals dolomite (CaCO3·MgCO3) and carnallite
(KCl·MgCl2·6H2O), but is most often obtained from seawater. Every cubic
162
kilometer of seawater contains about 1.3 billion kilograms of magnesium (12
billion pounds per cubic mile).
Magnesium burns with a brilliant white light and is used in pyrotechnics,
flares and photographic flashbulbs. Magnesium is the lightest metal that can
be used to build things, although its use as a structural material is limited
since it burns at relatively low temperatures. Magnesium is frequently
alloyed with aluminum, which makes aluminum easier to roll, extrude and
weld. Magnesium-aluminum alloys are used where strong, lightweight
materials are required, such as in airplanes, missiles and rockets. Cameras,
horseshoes, baseball catchers' masks and snowshoes are other items that
are made from magnesium alloys.
Magnesium oxide (MgO), also known as magnesia, is the second most
abundant compound in the earth's crust. Magnesium oxide is used in some
antacids, in making crucibles and insulating materials, in refining some
metals from their ores and in some types of cements. When combined with
water (H2O), magnesia forms magnesium hydroxide (Mg(OH)2), better known
as milk of magnesia, which is commonly used as an antacid and as a
laxative.
Hydrated magnesium sulphate (MgSO4·7H2O), better known as Epsom salt,
was discovered in 1618 by a farmer in Epsom, England, when his cows
refused to drink the water from a certain mineral well. He tasted the water
and found that it tasted very bitter. He also noticed that it helped heal
scratches and rashes on his skin. Epsom salt is still used today to treat minor
skin abrasions.
Other magnesium compounds include magnesium carbonate (MgCO3) and
magnesium fluoride (MgF2). Magnesium carbonate is used to make some
types of paints and inks and is added to table salt to prevent caking. A thin
163
film of magnesium fluoride is applied to optical lenses to help reduce glare
and reflections.
c. Calsium
Calcium is essential for human nutrition. Animals skeletons get their rigidity
primarily from calcium phosphate. The eggs of birds and shells of mollusks
are comprised of calcium carbonate. Calcium is also necessary for plant
growth. Calcium is used as a reducing agent when preparing metals from
their halogen and oxygen compounds; as a reagent in purification of inert
gases; to fix atmospheric nitrogen; as a scavenger and decarbonizer in
metallurgy; and for making alloys. Calcium compounds are used in making
lime, bricks, cement, glass, paint, paper, sugar, glazes, as well as for many
other uses.
Sources: The Romans prepared lime (called calx) in the first century, but
the metal was not discovered until 1808. Berzelius and Pontin prepared
calcium amalgam by electrolyzing lime in mercury. Davy isolated the impure
metal. The metal may be prepared by electrolysis of CaCl2 at a temperature
slightly above its melting point. Calcium is the fifth most abundant element
in the earth's crust, making up 3.22% of the earth, air, and oceans. Natural
forms of calcium include limestone (CaCO3), gypsum (CaSO4·2H2O), and
fluorite (CaF2). Apatite is the fluorophosphate or chlorophosphate of calcium.
d. Stronsium
Strontium was recognized as distinct from barium in 1790 by Adair Crawford
in a mineral sample from a mine near Strontian, Scotland. The element took
its name from the Scottish town. The metal was first isolated by Sir Humphry
Davy in 1808, by electrolysis. Strontium is a soft, silvery metal. When cut it
quickly turns a yellowish color due to the formation of strontium oxide
(strontia, SrO) . Finely powdered strontium metal is sufficiently reactive to
ignite spontaneously in air. It reacts with water quickly (but not violently like
164
the Group 1 metals) to produce strontium hydroxide and hydrogen gas.
Strontium and its compounds burn with a crimson flame and are used in
fireworks.
Uses:
Strontium is used for producing glass (cathode ray tubes) for color
televisions. It is also used in producing ferrite ceramic magnets and in
refining zinc. The world's most accurate atomic clock, accurate to one
second in 200 million years, has been developed using strontium atoms.
Strontium salts are used in flares and fireworks for a crimson color.
Strontium chloride is used in toothpaste for sensitive teeth. Strontium oxide
is used to improve the quality of pottery glazes. The isotope 90Sr is one of the
best long-lived, high-energy beta emitters known. It is used in cancer
therapy.
e. Barium
Uses: Barium is used as a "flashed getter" in vacuum tubes to remove the
last traces of gases. Barium is an important element in yttrium barium
copper oxide (YBCO) superconductors. An alloy of barium with nickel is used
in sparkplug wire. Hardness: 1.25 mohs Harmful effects: Barium compounds
that are water or acid soluble are highly poisonous. Barium powder can
ignite spontaneously in air. Characteristics: Barium is a metallic element
chemically resembling calcium but more reactive. Barium oxidizes very
easily in air and is also highly reactive with water or alcohol. Barium is most
commonly found as the mineral barite (BaSO4) and witherite (BaCO3)
f. Radium
Radium was discovered in 1898 by Marie S. Curie and her husband Pierre in
pitchblende (mainly uranium dioxide UO2). If pitchblende contains 50 percent
uranium oxides, about eight tons of it is needed to extract 1 gram of radium.
Already that year the Curies had discovered polonium, a radioactive element
whose properties they said were similar to bismuth's. Now, in radium - in the
165
form of radium bromide - they had discovered a further radioactive element
whose chemistry was very similar to that of group II metal barium. Metallic
radium was first isolated in 1910 by Marie S. Curie and Andre Debierne by
the electrolysis of a solution of pure radium chloride. The element's name
comes from the Latin word 'radius', meaning ray, after the rays emitted by
this radioactive element. In the discovery of radioactivity, chemists realized
that one of alchemy's dreams - the transmutation of elements - was possible.
Harmful effects: Radium is highly radioactive and hence carcinogenic.
Microscopic quantities of radium in the environment can lead to some
accumulation of radium in bone tissue. Radium, like calcium, is a group II
element and our bodies treat it in a similar way.
Characteristics:
Radium is a silvery-white metal. It is highly radioactive and its decay
product, radon gas, is also radioactive. One result of radium's intense
radioactivity is that the metal and its compounds glow in the dark. When it is
exposed to air, it reacts with nitrogen to quickly form a black coating of
radium nitride. Radium's chemistry is similar to that of the other alkali earth
metals. It reacts very vigorously with water to form hydrogen gas and radium
hydroxide. It reacts with even more vigorously with hydrochloric acid to form
radium chloride.
Uses:
Radium was used in the production of luminous paints, but this is now
considered too dangerous. Radium chloride was used medicinally to produce
radon gas for cancer treatment. Safer treatments are now available.
166
CHAPTER II
IIB ELEMENTS
II (ZINC), CADMIUM, MERCURY
These elements formed Group IIB of Mendeleef 's original periodic table. As
we have seen in Chapter 13, zinc does not show very marked 'transition-
metal' characteristics. The other two elements in this group, cadmium and
mercury, lie at the ends of the second and third transition series (Y-Cd, La-
Hg) and, although they resemble zinc in some respects in showing a
predominantly 4- 2 oxidation state, they also show rather more transition-
metal characteristics. Additionally, mercury has characteristics, some of
which relate it quite closely to its immediate predecessors in the third
transition series, platinum and gold, and some of which are decidedly
peculiar to mercury.
PROPERTIES OF THE ELEMENTS
Elem
ent
Atom
ic
Outer
electrons
Atomi
c
radius
Densit
y
m.p
.
b.p
.
lonisation
energy*
Heat of
atomisati
167
num
ber
(nm) (g/ ) (K) (K) (kJ/mol) on
(kJ/mol)
Zn
Cd
Hg
30
48
80
[Ar]3 4
[Kr]4
[Ar]4 5
0.133
0.149
0,152
7.13
8.65
13,53
693
594
234
11
81
10
38
63
0
1st 2nd
906
1734
816
1630
1007
1809
131
286
61
The table shows that all three elements have remarkably low melting points
and boiling points—an indication of the weak metallic ^bonding, especially
notable in mercury. The low heat of atomisation of the latter element
compensates to some extent its higher ionisation energies, so that, in
practice, all the elements of this group can form cations M2 + in aqueous
solution or in hydrated salts; anhydrous mercury(II) compounds are generally
covalent.
ZINC
Isotopes: There are 21 known isotopes of zinc, 5 stable and 16 unstable.
Natural zinc contains the 5 stable isotopes. Properties: Zinc has a melting point of
419.58°C, boiling point of 907°C, specific gravity of 7.133 (25°C), with a valence of
2. Zinc is a lustous blue-white metal. It is brittle at low temperatures, but becomes
168
malleable at 100-150°C. It is a fair electrical conductor. Zinc burns in air at high red
heat, evolving white clouds of zinc oxide.
Uses: Zinc is used to form numerous alloys, including brass, bronze,
nickel silver, soft solder, Geman silver, spring brass, and aluminum solder.
Zinc is used to make die castings for use in the electrical, automotive, and
hardware industries. The alloy Prestal, consisting of 78% zinc and 22%
aluminum, is nearly as strong as steel yet exhibits superplasticity. Zinc is
used to galvanize other metals to prevent corrosion. Zinc oxide is used in
paints, rubbers, cosmetics, plastics, inks, soap, batteries, pharmaceuticals,
and many other products. Other zinc compounds are also widely used, such
as zinc sulfide (luminous dials and fluorescent lights) and ZrZn2
(ferromagnetic materials). Zinc is an essential element for humans and other
animal nutrition. Zinc-deficient animals require 50% more food to gain the
same weight as animals with sufficient zinc. Zinc metal is not considered
toxic, but if fresh zinc oxide is inhaled it can cause a disorder referred to as
zinc chills or oxide shakes.
Sources: The primary ores of zinc are sphalerite or blende (zinc
sulfide), smithsonite (zinc carbonate), calamine (zinc silicate), and franklinite
(zinc, iron, and manganese oxides). An old method of producing zinc was by
reducing calamine with charcoal. More recently, it has been obtained by
roasting the ores to form zinc oxide and then reducing the oxide with carbon
or coal, followed by distillation of the metal.
CADMIUM
THE ELEMENT
169
Cadmium is usually found in zinc ores and is extracted from them along with
zinc (p. 416); it may be separated from the zinc by distillation (cadmium is
more volatile than zinc) or by electrolytic deposition. Cadmium is a soft
metal, which forms a protective coating in air, and bums only on strong
heating to give the brown oxide CdO. It dissolves in acids with evolution of
hydrogen. It is used as a protective agent, particularly for iron, and is more
resistant to corrosion by sea water than, for example, zinc or nickel. In its
chemistry, cadmium exhibits exclusively the oxidation state -f 2 in both ionic
and covalent compounds. The hydroxide is soluble in acids to give
cadmium(II) salts, and slightly soluble in concentrated alkali where
hydroxocadmiates are probably formed; it is therefore slightly amphoteric. It
is also soluble in ammonia to give ammines, for example [Cd(NH3)4]2+. Of
the halides, cadmiumill) chloride is soluble in water, but besides [Cd(H2O)J2
+ ions, complex species [CdCl]*, [CdQ3]~ and the undissociated chloride
[CdCl2] exist in the solution, and addition of chloride ion increases the
concentrations of these chloro-complexes at the expense of Cd2+(aq) ions.
Solid cadmium(II) iodide CdI2 has a layer lattice' — a structure intermediate
between one containing Cd2* and I~ ions and one containing CdI2 molecules
— and this on vaporisation gives linear, covalent I — Cd — I molecules. In
solution, iodo-complexes exist, Cadmium(ll} sulphide, CdS, is a canary-
yellow solid, precipitated by addition of hydrogen sulphide (or sulphide ion)
to an acid solution
of a cadmium(II) salt; presence of chloride ion may reduce the concentration
of Cd2+(aq) sufficiently to prevent precipitation. Complexes of cadmium
include, besides those already mentioned, a tetracyanocadmiate
[Cd(CN)4]2~ which in neutral solution is sufficiently unstable to allow
precipitation of cadmium(II) sulphide by hydrogen sulphide. Octahedral
[CdCl6]4" ions are known in the solid state, as, for example, K4CdCl6.
MERCURY
THE ELEMENT
170
Mercury has been known for many centuries, perhaps because its extraction
is easy; it has an almost unique appearance, it readily displaces gold from its
ores and it forms amalgams with many other metals—all properties which
caused the alchemists to regard it as one of the "fundamental' substances. It
occurs chiefly as cinnabar, the red sulphide HgS, from which it is readily
extracted either by roasting (to give the metal and sulphur dioxide) or by
heating with calcium oxide; the metal distils off and can be purifyied by
vacuum distillation. Mercury has a large relative atomic mass, but, like zinc
and cadmium, the bonds in the metal are not strong. These two factors
together may account for the very low melting point and boiling point of
mercury. The low boiling point means that mercury has an appreciable
vapour pressure at room temperature; 1 m3 of air in equilibrium with the
metal contains 14 mg of vapour, and the latter is highly toxic. Exposure of
mercury metal to any reagent which produces volatile mercury compounds
enhances the toxicity. The metal is slowly oxidised by air at its boiling point,
to give red mercury(II) oxide; it is attacked by the halogens (which cannot
therefore be collected over mercury) and by nitric acid. (The reactivity of
mercury towards acids is further considered on pp. 436, 438.) It forms
amalgams—liquid or solid—with many other metals; these find uses as
reducing agents (for example with sodium, zinc) and as dental fillings (for
example with silver, tin or copper).
USES
Mercury is extensively used in various pieces of scientific apparatus, such as
thermometers, barometers, high vacuum pumps, mercury lamps, standard
cells (for example the Weston cell), and so on. The metal is used as the
cathode in the Kellner-Solvay cell (p. 130). Mercury compounds (for example
mercury(II) chloride) are used
in medicine because of their antiseptic character. The artificial red
mercury(II) sulphide is the artist's 'vermilion1. Mercury(II) sulphate is a
catalyst in the manufacture of ethanal from ethyne: C2H2 + H2O ^^ CH3.
CHO
171
COMPOUNDS OF MERCURY
The chemistry of mercury compounds is complicated by the
equilibrium
The relevant redox potentials are :
Hg2+(aq) 4- 2e~ -> Hg(I) : E^ = 0.85 V
+ 2e~ -> 2Hg(I) : E^ = 0.79 V
Hence mercury is a poor reducing agent; it is unlikely to be attacked by acids
unless these have oxidising properties (for example nitric acid), or unless the
acid anion has the power to form complexes with one or both mercury
cations Hg2+ or Hgf +, so altering the E^ values. Nitric acid attacks
mercury, oxidising it to Hg2+(aq) when the acid is concentrated and in
excess, and to Hg2+(aq) when mercury is in excess and the acid dilute.
Hydriodic acid HI(aq) attacks mercury, because mercury(II) readily forms
iodo-complexes.
Oxidation state +1
The mercury(I) ion has the structure so that each mercury atom is losing one
electron and sharing one electron, i.e. is 'using' two valency electrons. The
existence of Hg| +
has been established by experiments in solution and by X-ray diffraction
analysis of crystals of mercury(I) chloride, Hg2Cl2 where the mercury ions
are in pairs with the chloride ions adjacent, i.e. CP *Hg—Hg+. Cl~. (It is now
known that mercury can
also form species Hg^ up to Hgg+ ; cadmium also gives Cd^+, and other
polymetallic cations, for example Bi^ are known.) The ion Hg|+(aq) tends to
disproportionate, especially if the concentration of Hg2 +(aq) is reduced, for
example by precipitation or by complex formation. However, the equilibrium
can be moved to the left by using excess of mercury, or by avoiding aqueous
solution. Thus, heating a mixture of mercury and solid mercury(II) chloride
gives mercury(I) chloride, which sublimes off:
Hg + HgCl2 -> Hg2Cl2 The product, commonly called calomel, is a white
solid, insoluble in water; in its reactions (as expected) it shows a tendency to
172
produce mercury(II) and mercury. Thus under the action of light, the
substance darkens because mercury is formed; addition of aqueous
ammonia produces the substance H2N—Hg—Hg—Cl, but this also darkens on
standing, giving H2N—Hg—Cl and a black deposit of mercury. Mercury(I) ions
can be produced in solution by dissolving excess mercury in dilute nitric acid:
6Hg + 8H+ + 2NO3~ -» 3Hg|+ + 2NO + 4H2O
From the acid solution white hydrated mercury(I) nitrate Hg2(NO3)2.2H2O
can be crystallised out; this contains the ion [H2O-Hg-Hg-H2O]2 + which is
acidic (due to hydrolysis) in aqueous solution. Addition of chloride ion
precipitates mercury(I) chloride.
Oxidation state + 2
Mercury(II) oxide, HgO, occurs in both yellow and red forms; the yellow form
is precipitated by addition of hydroxide ion to a solution containing
mercury(II) ions, and becomes red on heating. Mercury(II) oxide loses oxygen
on heating. Mercury(II) chloride is obtained in solution by dissolving
mercury(II) oxide in hydrochloric acid; the white solid is obtained as a
sublimate by heating mercury(II) sulphate and solid sodium chloride: HgSO4
+ 2NaCl -» HgCl2 + Na2SO4
The aqueous solution has a low conductivity, indicating that mercury(II)
chloride dissolves essentially as molecules Cl—Hg—Cl and these linear
molecules are found in the solid and vapour. A solution of mercury(II)
chloride is readily reduced, for example by tin(II) chloride, to give first white
insoluble mercury(I) chloride and then a black metallic deposit of mercury.
The complexes formed from mercury(II) chloride are considered below.
Mercury(H) iodide, HgI2, is coloured either red or yellow, and is precipitated
(yellow, turning red) by adding the stoichiometric amount of iodide ion to a
solution containing mercury(II): Hg2+ +2r-»HgI2
Addition of excess iodide gives a complex (see below).
Mercury(II) sulphate and nitrate are each obtained by dissolving mercury in
the appropriate hot concentrated acid; the sulphate is used as a catalyst.
173
MercuryiH) sulphide, HgS, again appears in two forms, red (found naturally
as cinnabar) and black, as precipitated by hydrogen sulphide from a solution
containing Hg(II) ions.
Complexes
Mercury (I) forms few complexes, one example is the linear [H2O- Hg-Hg—
H2O]2 + found in the mercury(I) nitrate dehydrate (above, p. 437). In
contrast, mercury(II) forms a wide variety of complexes, with some
peculiarities: (a) octahedral complexes
are rare, (b) complexes with nitrogen as the donor atom are common, (c)
complexes are more readily formed with iodine than with other halogen
ligands. Mercury(II) halides, HgX2, can be regarded as neutral, 2- co-ordinate
linear complexes X—Hg- X. X is readily replaced; addition of ammonia to a
solution of mercury(II) chloride gives a
white precipitate NH2—Hg—Cl; in the presence of concentrated ammonium
chloride, the same reagents yield the diamminomercury(II) cation, [NH3—Hg
—NH3]2+, which precipitates as [Hg(NH3)2]Cl2. In presence of excess
chloride ion, mercury(II) chloride gives complexes [HgCl3]~ and [HgCl4]2~,
but the corresponding iodo-complex [HgI4]2", from mercury(II) iodide and
excess iodide, is more stable. (It is rare for iodo-complexes to form at all and
very rare to find them with stabilities greater than those of thloro-
complexes.) In both solid HgI2 and the complex [HgI4]2~the mercury is
tetrahedrally 4-co-ordinated. The [HgI4]2" ion has a characteristic reaction
with ammonia—a trace produces a yellow colour and more ammonia gives a
brown precipitate. (An alkaline solution containing [HgI4]2~ ions is therefore
used as a test for ammonia; it is sometimes called Messier's reagent.)
Insoluble salts of the anion [HgI4]2~ are known, for example Cu2[HgI4] (red)
174
CHAPTER II MATTER
ELEMENTS OF GROUP III A
BORON (B)
Physical Information
1. Atomic Number : 5
2. Relative Atomic Mass (12C=12.000) : 10.81
3. Melting Point/K : 2573
4. Boiling Point/K : 3931
5. Density/kg m-3 : 2340 (293K)
6. Liquid range : 1851 K
7. Ground State Electron Configuration : [He]2s2 2p1
8. Electron Affinity (M-M-)/kJ mol-1 : -15
Discovery
Boron compounds have been known for thousands of years, but the element
was not isolated until 1808 by Sir Humphry Davy, Joseph-Louis Gay-Lussac (1778-
1850) and Louis Jaques Thenard (1777-1857) in London. This was accomplished
through the reaction of boric acid (H3BO3) with potassium.
Appearance
The element is a grey powder, but is not found free in nature.
Source
The element is not found free in nature, but occurs as orthoboric acid usually
found in certain volcanic spring waters and as borates in boron and colemantie.
175
Ulexite, another boron mineral, is interesting as it is nature's own version of "fiber
optics."
Important sources of boron are ore rasorite (kernite) and tincal (borax ore).
Both of these ores are found in the Mojave Desert. Tincal is the most important
source of boron from the Mojave. Extensive borax deposits are also found in Turkey.
Boron exists naturally as 19.78% 10B isotope and 80.22% 11B isotope. High-
purity crystalline boron may be prepared by the vapor phase reduction of boron
trichloride or tribromide with hydrogen on electrically heated filaments. The impure
or amorphous, boron, a brownish-black powder, can be obtained by heating the
trioxide with magnesium powder.
Boron of 99.9999% purity has been produced and is available commercially.
Elemental boron has an energy band gap of 1.50 to 1.56 eV, which is higher than
that of either silicon or germanium.
Uses
Amorphous boron is used in pyrotechnic flares to provide a distinctive green
colour, and in rockets as an igniter. The most important compounds of boron are
boric (or boracic) acid, widely used as a mild antiseptic, and borax which serves as
a cleansing flux in welding and as a water softener in washing powders. Boron
compounds are also extensively used in the manufacture of borosilicate glasses.
Other boron compounds show promise in treatingarthritis. The isotope boron 10 is
used as a control for nuclear reactors, as a shield for nuclear radiation, and in
instruments used for detecting neutrons. Demand is increasing for boron filaments,
a high-strength, low-density material chiefly employed for advanced aerospace
structures.
Boron used as a deoxidiser and flux in metallurgy, in the manufacture of
BoroSilicate Glass, in the bearings of turbines the form of metallic borides where
hardness and resistance to corrosion is required, and in the nuclear industry as a
moderator for neutrons.
The following uses for boron are gathered from a number of sources as well as from
anecdotal comments. I'd be delighted to receive corrections as well as additional
referenced uses (please use the feedback mechanism to add uses).
176
amorphous boron is used in pyrotechnic flares (distinctive green colour), and
rockets (as an igniter)
boric, or boracic, acid, is used as a mild antiseptic
borax, Na2B4O7.10H2O, is a cleansing flux in welding
borax, Na2B4O7.10H2O is a water softener in washing powders
boron compounds are used in production of enamels for covering steel of
refrigerators, washing machines, etc.
boron compounds are extensively used in the manufacture of enamels and
borosilicate glasses
boron compounds show promise in treating arthritis
10B is used as a control for nuclear reactors, as a shield for nuclear radiation,
and in instruments used for detecting neutrons
boron nitride is as hard as diamond. It behaves like an electrical insulator, but
conducts heat like a metal. It also has lubricating properties similar to
graphite
the hydrides are sometimes used as rocket fuels
boron filaments, a high-strength, lightweight material, are used for advanced
aerospace structures, .
lightweight compounds used for aerospace structures
boron filaments used in fibre optics research
Boric Acid is also used in North America for the control of cockroaches,
silverfish, ants, fleas, and other insects.
Biological Role
Elemental boron is not considered a poison, and indeed is essential to plants,
but assimilation of its compounds has a cumulative toxic effect.
General Information
177
Elemental boron has an energy band gap of 1.50 to 1 .56 eV, which is higher
than that of either silicon or germanium. It has interesting optical characteristics,
transmitting portions of the infrared only. It is a poor conductor of electricity at
room temperature, but a good conductor at high temperatures. Boron in its
crystalline form is a very hard solid with a quaesi-metallic sheen, and in its
amorphous form is a brown powder.
Reactions
Boron burns with a brilliant flame in oxygen to form boron trioxide.
Boron burns in air when heated to give a mixture of boron trioxide and Boron
Nitride.
Boron is relatively inert and must be in a highly divided state to react with
acids or alkalis.
Boron is oxidised by nitric acid to boric acid.
Boron reacts with fused sodium hydroxide to form sodium borate and
hydrogen.
Reaction of boron with air
The behaviour of boron to air depends upon the crystallinity of the sample,
temperature, particle size, and purity. By and large, boron does not react with air at
room temperature. At higher temperatures, boron does burn to form boron (III)
oxide, B2O3.
4B + 3O2(g) → 2B2O3(s)
Reaction of boron with water
Boron does not react with water under normal conditions.
Reaction of boron with the halogens
Boron reacts vigorously with the halogens fluorine, F2, chlorine, Cl2, bromine, Br2 to
to form the trihalides boron(III) fluoride, BF3, boron(III) chloride, BCl3, and boron(III)
bromide, BBr3 respectively.
2B(s) + 3F2(g) → 2BF3(g)
178
2B(s) + 3Cl2(g) → 2BCl3(g)
2B(s) + 3Br2(g) → 2BF3(l)
Reaction of boron with acids
Crystalline boron does not react with boiling hydrochloric acid, HCl, or boiling
hydrofluoric acid, HF. Powdered boron oxidizes slowly when treated with
concentrated nitric acid, HNO3.
Detection and Analysis
Boron is detected by converting the material under analysis to Borax by
heating with concentrated nitric acid and then heating with concentrated sulphuric
acid and ethanol to form ethyl borate, which burns with a green flame.
Handling
Elemental boron and the borates are not considered to be toxic, and they do
not require special care in handling. However, some of the more exotic boron
hydrogen compounds are definitely toxic and do require care.
Isolation
It is not normally necessary to make boron in the laboratory and it would
normally be purchased as it is available commercially. The most common sources of
boron are tourmaline, borax [Na2B4O5(OH)4.8H2O], and kernite [Na2B4O5(OH)4.2H2O].
It is difficult to obtain pure. It can be made through the magnesium reduction of the
oxide, B2O3. The oxide is made by melting boric acid, B(OH)3, which in turn is
obtained from borax.
B2O3 + 3Mg → 2B + 3MgO
Samm amounts of high purity boron are available through the thermal
decomposition of compounds such as BBr3 with hydrogen gas using a heated
tantalum wire. Results are better with hot wires at tmeperatures over 1000°C.
179
ALUMUNIUM (Al)
Physical Information
1. Atomic Number : 13
2. Relative Atomic Mass (12C=12.000) : 26.982
3. Melting Point/K : 933
4. Boiling Point/K : 2740
5. Density/kg m-3 : 2698 (293K)
6. Ground State Electron Configuration : [Ne ]3s2 3p1
7. Electron Affinity (M-M-)/kJ mol-1 : -44
Discovery
(L. alumen: alum) The ancient Greeks and Romans used alum as an
astringent and as a mordant in dyeing. In 1761 de Morveau proposed the name
alumine for the base in alum, and Lavoisier, in 1787, thought this to be the oxide of
a still undiscovered metal.
Wohler is generally credited with having isolated the metal in 1827, although
an impure form was prepared by Oersted two years earlier. In 1807, Davy proposed
the name aluminium for the metal, undiscovered at that time, and later agreed to
change it to aluminum. Shortly thereafter, the name aluminum was adopted to
conform with the "ium" ending of most elements.
Aluminium was also the accepted spelling in the U.S. until 1925, at which
time the American Chemical Society decided to use the name aluminum thereafter
in their publications.
Appearance
180
Aluminium is a hard and strong, silvery-white metal. An oxide film prevents it
from reacting with air and water.
Occurrence
Aluminium is highly reactive and does not occur in the free state. However, it
is widely distributed and it is third in abundance on earth after Oxygen and Silicon.
Aluminium exists primarily as Alumino-Silicates (i.e. as Felspar, NaAlSi3O8, or
KAlSi3O8, or CaAl2Si2O8), in igneous rocks and as Clays, H4Al2Si2O9, in
sedimentary rocks.
Aluminium has three principal ores
Gibbsite or Hydrargillite, Al2O3.3H2O,
Bauxite, Al2O3.2H2O, Diaspore, Al2O3.H2O, and
Cryolite, AlF3.3HF.
Aluminium also occurs in the form of its Aluminium Oxide, Al2O3, in the
semiprecious stones. The colouration in these gems is caused by trace quantities of
impurities :
Emerald, Sapphire (coloured blue by Cobalt Oxide, CoO), and Ruby (coloured
blue by Chromium Oxide, Cr2O3).
Source
The method of obtaining aluminum metal by the electrolysis of alumina
dissolved in cryolite was discovered in 1886 by Hall in the U.S. and at about the
same time by Heroult in France. Cryolite, a natural ore found in Greenland, is no
longer widely used in commercial production, but has been replaced by an artificial
mixture of sodium, aluminum, and calcium fluorides.
Aluminum can now be produced from clay, but the process is not
economically feasible at present. Aluminum is the most abundant metal to be found
in the earth's crust (8.1%), but is never found free in nature. In addition to the
minerals mentioned above, it is also found in granite and in many other common
minerals. Most commercially produced aluminium is obtained by the Bayer process
of refining bauxite. In this process the bauxite is refined to pure aluminium oxide,
which is mixed with cryolite and then electrolytically reduced to pure aluminium.
Uses
181
Aluminium is used in an enormous variety of products, due to its particular
properties. It has low density, is non-toxic, has a high thermal conductivity, has
excellent corrosion resistance, and can be easily cast, machined and formed. It is
also non-magnetic and non-sparking. It is the second most malleable metal and the
sixth most ductile. It is therefore extensively used for kitchen utensils, outside
building decoration, and in any area where a strong, light, easily constructed
material is needed.
The electrical conductivity of aluminium is about 60% that of copper per unit
area of cross-section, but it is nevertheless used in electrical transmission lines
because of its low density. Alloys of aluminium with copper, manganese,
magnesium and silicon are of vital importance in the construction of aeroplanes and
rockets. Aluminium, when evaporated in a vacuum, forms a highly reflective coating
for both light and heat which does not deteriorate as does a silver coating. These
aluminium coatings are used for telescope mirrors, in decorative paper, packages
and toys, and have many other uses.
The following uses for aluminium are gathered from a number of sources as well as
from anecdotal comments. I'd be delighted to receive corrections as well as
additional referenced uses (please use the feedback mechanism to add uses).
cans and foils
kitchen utensils
outside building decoration
industrial applications where a strong, light, easily constructed material is
needed
although its electrical conductivity is only about 60% that of copper per area
of cross section, it is used in electrical transmission lines because of its
lightness and price
alloys are of vital importance in the construction of modern aircraft and
rockets
aluminium, evaporated in a vacuum, forms a highly reflective coating for
both visible light and radiant heat. These coatings soon form a thin layer of
182
the protective oxide and do not deteriorate as do silver coatings. These
coatings are used for telescope mirrors, decorative paper, packages, toys,
and in many other uses
the oxide, alumina, occurs naturally as ruby, sapphire, corundum, and emery,
and is used in glass making and refractories. Synthetic ruby and sapphire are
used in the construction of lasers
Biological Role
Aluminium has no known biological role. It can be accumulated in the body
from daily intake, and at one time was suggested as a potential causative factor in
Alzheimer’s disease (senile dementia).
General Information
The ancient Greeks and Romans used alum (potassium aluminium sulfate) in
medicine as an astringent, and in dyeing as a mordant. Sir Humphry Davy proposed
the name aluminum for the element, which was undiscovered at the time, and later
agreed to change it to aluminium. Aluminium oxide, alumina, occurs naturally as
corundum and emery, and is used in glass-making and refractories. The precious
stones ruby and sapphire contain aluminium with very small amounts of specific
impurities.
Reactions
Aluminium reacts rapidly with the Oxygen in air to form Aluminium Oxide,
Al2O3, which forms a tough layer on the surface of the metal, thereby preventing
any further reaction. This aluminium oxide layer can be thickened by a process
known as anodising, which involves using the aluminium object as the anode in an
electrolytic cell.
Reaction of aluminium with air
Aluminium is a silvery white metal. The surface of aluminium metal is covered with
a thin layer of oxide that helps protect the metal from attack by air. So, normally,
aulumium metal does not react with air. If the oxide layer is damaged, the
183
aluminium metal is exposed to attack. Aluminium will burn in oxygen with a brilliant
white flame to form the trioxide alumnium(III) oxide, Al2O3.
4Al(s) + 3O2(l) → 2Al2O3(s)
Reaction of aluminium with water
Aluminium is a silvery white metal. The surface of aluminium metal is covered with
a thin layer of oxide that helps protect the metal from attack by air. So, normally,
aulumium metal does not react with air. If the oxide layer is damaged, the
aluminium metal is exposed to attack, even by water.
Reaction of aluminium with the halogens
Aluminium metal reacts vigorously with all the halogens to form aluminium halides.
So, it reacts with chlorine, Cl2, bromine, I2, and iodine, I2, to form respectively
aluminium(III) chloride, AlCl3, aluminium(III) bromide, AlBr3, and aluminium(III)
iodide, AlI3.
2Al(s) + 3Cl2(l) → 2AlCl3(s)
2Al(s) + 3Br2(l) → Al2Br6(s)
2Al(s) + 3I2(l) → Al2I6(s)
Reaction of aluminium with acids
Aluminium metal dissolves readily in dilute sulphuric acid to form solutions
containing the aquated Al(III) ion together with hydrogen gas, H2. The corresponding
reactions with dilute hydrochloric acid also give the aquated Al(III) ion.
Concentrated nitric acid passivates aluminium metal.
2Al(s) + 3H2SO4(aq) → 2Al3+(aq) + 2SO42-(aq) + 3H2(g)
2Al(s) + 6HCl(aq) → 2Al3+(aq) + 6Cl-(aq) + 3H2(g)
Reaction of aluminium with bases
184
Aluminium dissolves in sodium hydroxide with the evolution of hydrogen gas, H2,
and the formation of aluminates of the type [Al(OH)4]-.
2Al(s) + 2NaOH(aq) + 6H2O → 2Na+(aq) + 2[Al(OH)4]- + 3H2(g)
Isolation
Isolation: aluminium would not mormally be made in the laboratory as it is so
readily available commercially.
Aluminium is mined in huge scales as bauxite (typically Al2O3.2H2O). Bauxite
contains Fe2O3, SiO2, and other impurities. In order to isolate pure aluminium, these
impurities must be removed from the bauxite. This is done by the Bayer process.
This involves treatment with sodium hydroxide (NaOH) solution, which results in a
solution of sodium aluminate and sodium silicate. The iron remains behind as a
solid. When CO2 is blown through the resulting solution, the sodium silicate stays in
solution while the aluminium is precipitated out as aluminium hydroxide. The
hydroxide can be filtered off, washed, and heated to form pure alumina, Al2O3.
The next stage is formation of pure aluminium. This is obtained from the pure
Al2O3 by an electrolytic method. Electrolysis is necessary as aluminium is so
electropositive. It seems these days that electrolysis of the hot oxide in a carbon
lined steel cell acting as the cathode with carbon anodes is most common.
GALIUM (Ga)
Physical Information
1. Atomic Number : 31
185
2. Relative Atomic Mass (12C=12.000) : 69.723
3. Melting Point/K : 303
4. Boiling Point/K : 2676
5. Density/kg m-3 : 5907 (293K)
6. Ground State Electron Configuration : [Ar] 3d10 4s2 4p1
7. Electron Affinity (M-M-)/kJ mol-1 : -36
Discovery
(L. Gallia: France; also from Latin, gallus, a translation of "Lecoq", a cock)
Predicted and described by Mendeleev as ekaaluminum. Gallium was an element
whose existence was predicted by Mendeleev in 1871. He predicted that the then
unknown element gallium should resemble aluminium in its properties. He
suggested therefore the name ekaaluminium (symbol Ea). His predictions for the
properties of gallium are remarkably close to the reality. Gallium was discovered
spectroscopically by Paul-Emile Lecoq de Boisbaudran in 1875, who in the same
year obtained the free metal by electrolysis of a solution of the hydroxide Ga(OH)3
in KOH.
Appearance
Gallium is a silvery, glass-like, soft metal.
Source
Gallium is present in trace amounts in the minerals diaspore, sphalerite,
germanite, bauxite and coal. The free metal can be obtained by electrolysis of a
solution of gallium(III) hydroxide in potassium hydroxide.
Reactions
Reaction with air: mild, → Ga2O3
Reaction with 6 M HCl: mild, →H2, GaCl3
Reaction with 6 M NaOH: mild, → H2, [Ga(OH4)]2-
Uses
Gallium readily alloys with most metals, and is used especially in low-melting
alloys. It has a high boiling point, which makes it ideal for recording temperatures
186
that would vaporise a thermometer. It has found recent use in doping
semiconductors and producing solid-state devices such as transistors.
The following uses for gallium are gathered from a number of sources as well as
from anecdotal comments. I'd be delighted to receive corrections as well as
additional referenced uses (please use the feedback mechanism to add uses).
gallium wets glass or porcelain, and forms a brilliant mirror when it is painted
on glass
used for doping semiconductors and producing solid-state devices such as
transistors
gallium arsenide converts electricity into coherent light
alloying
90 tons of gallium (2 or 3 years of world production) is used to detect solar
neutrinos by the use of the reaction: nu + 71Ga > 71Ge + e-. The rate,
although very low (less than 1 interaction per day in 30 tonnes of Ga) makes
gallium unique for this purpose. Two experiments are running : - GALLEX
using 30 tons in the Gran Sasso underground laboratory (Italy) and SAGE with
60 tons in the Baksan laboratory in Caucasus (Russia). [thanks Michel]
Biological Role
Gallium has no known biological role. It is non-toxic.
General Information
Gallium reacts with acids and alkalis. It has the longest liquid range of all
elements, and can be liquid near room temperatures - it can melt in the hand. It
also expands as it freezes, which is unusual for a metal, by 3.1%. Gallium wets glass
or porcelain, and forms a brilliant mirror when painted on glass.
Isolation
Isolation: gallium is normally a byproduct of the manufacture of aluminium.
The purification of bauxite by the Bayer process results in concentration of gallium
187
in the alkaline solutions from an aluminium:gallum ratio from 5000 to 300.
Electrolysis using a mercury electrode gives a further concentration and further
electrolysis using a stainless steel cathode of the resulting sodium gallate affords
liquid gallium metal.
Very pure gallium requires a number of further processes ending with zone refining
to make very pure gallium metal.
INDIUM (In)
Physical Information
Atomic Number : 49
Relative Atomic Mass (12C=12.000) : 114.82
188
Melting Point/K : 429
Boiling Point/K : 2353
Density/kg m-3 : 7310 (298K)
Ground State Electron Configuration : [Kr]4d105s25p1
Electron Affinity (M-M-)/kJ mol-1 : -34
Discovery
(from the brilliant indigo line in its spectrum) Discovered by Reich and
Richter, who later isolated the metal. Until 1924, a gram or so constituted the
world's supply of this element in isolated form. It is probably about as abundant as
silver. About 4 million troy ounces of indium are now produced annually in the Free
World. Canada is presently producing more than 1,000,000 troy ounces annually.
Appearance
Indium is a very soft, silvery-white metal with a brilliant lustre.
Source
Indium is often associated with zinc minerals and iron, lead and copper ores.
It is commercially produced from the zinc minerals, usually as a by-product.
Uses
Indium has semiconductor uses in transistors, thermistors and
photoconductors. It is also used to make low-temperature alloys; for example, an
alloy of 24% indium-76% gallium is liquid at room temperature. Indium can also be
plated on to metal and evaporated on to glass to give a mirror with better
resistance to corrosion than silver. A tiny long-lived indium battery has been
devised to power new electronic watches. The following uses for indium are
gathered from a number of sources as well as from anecdotal comments. I'd be
delighted to receive corrections as well as additional referenced uses (please use
the feedback mechanism to add uses).
used in making bearing alloys, germanium transistors, rectifiers, thermistors,
and photoconductors
it can be plated onto metal and evaporated onto glass, forming a mirror as
good as those made with silver, but with more resistance to atmospheric
corrosion
189
photocells
used to make low-melting alloys, alloyed with gallium
indium is used in solders
Biological Role
Indium has no known biological role but has been shown to cause birth
defects in unborn children. It has low toxicity.
General Information
Indium is stable in air and with water, but reacts with acids.
Isolation
Isolation: indium would not normally be made in the laboratory as it is
commercially available. Indium is a byproduct of the formation of lead and zinc.
Indium metal is isolated by the electrolysis of indium salts in water. Further
processes are required to make very pure indium for electronics purposes.
THALIUM (Tl)
Physical Information
Atomic Number : 81
Relative Atomic Mass (12C=12.000) : 204.38
Melting Point/K : 576.7
Boiling Point/K : 1730
Density/kg m-3 : 11850 (293K)
Ground State Electron Configuration : [Xe] 4f14 5d10 6s2 6p1
Electron Affinity (M-M-)/kJ mol-1 : -30
190
Discovery
(Gr. thallos: a green shoot or twig) Thallium was discovered spectroscopically
in 1861 by Crookes. The element was named after the beautiful green spectral line,
which identified the element. The metal was isolated both by Crookes and by Lamy
in 1862 at about the same time.
Appearance
Thallium is a soft, silvery metal, but it soon develops a bluish-grey tinge as
the oxide forms if it is exposed to the air. Thallium is similar to lead in many of its
physical properties.
Source
Thallium is found in several ores, one of which is pyrites, used in the
production of sulphuric acid. The commercial source of thallium is as a by-product of
pyrites roasting in sulphuric acid production. It can also be obtained from the
smelting of lead and zinc ores. Thallium is also present in manganese nodules found
on the ocean floor.
Uses
Thallium sulfate has been widely employed as a rodenticide and ant killer. It
is odorless and tasteless, giving no warning of its presence. Its use, however, has
been prohibited in the U.S. since 1975 as a household insecticide and rodenticide.
The electrical conductivity of thallium sulfide changes with exposure to infrared
light, and this compound is used in photocells. Thallium bromide-iodide crystals
have been used as infrared optical materials. Thallium has been used, with sulfur or
selenium and arsenic, to produce low melting glasses with become fluid between
125 and 150C. These glasses have properties at room temperatures similar to
ordinary glasses and are said to be durable and insoluble in water. Thallium oxide
has been used to produce glasses with a high index of refraction, and is used in the
manufacture of photo cells. Thallium has been used in treating ringworm and other
skin infections; however, its use has been limited because of the narrow margin
between toxicity and therapeutic benefits. The following uses for thallium are
gathered from a number of sources as well as from anecdotal comments. I'd be
191
delighted to receive corrections as well as additional referenced uses (please use
the feedback mechanism to add uses).
the sulphate was widely used as a rodenticide and ant killer. It is odourless
and tasteless, giving no warning of its presence
the electrical conductivity of thallium sulphide changes with exposure to
infrared light, and so it is used in photocells
thallium bromide-iodide crystals are used as infrared detectors
used, with sulphur or selenium and arsenic, to produce low melting glasses
which become fluid between 125 and 150°C
originally used in treating ringworm and other skin infections. Its use was
limited because of the narrow margin between toxicity and therapeutic
benefits
A mercury-thallium alloy, which forms a eutectic at 8.5% thallium, freezes at -
60°C, some 20° below the freezing point of mercury
Biological Role
Thallium has no known biological role. It is very toxic and teratogenic.
Contact of the metal with the skin is dangerous, and there is evidence that the
vapour is both teratogenic and carcinogenic.
General Information
Thallium is soft, malleable and can be cut with a knife. It tarnishes readily in
moist air and reacts with steam to form the hydroxide. It is attacked by all acids,
most rapidly nitric acid.
Isolation
Isolation: thallium metal would not normally be made in the laboratory as it is
available commercially. Crude thallium is present as a component in flue dust along
with arsenic, cadmium, indium, germanium, lead, nickel, selenium, tellurium, and
zinc. This is done by dissolving in dilute acid, precipitating out lead sulphate, and
then adding HCl to precipitate thallium chloride, TlCl. Further purification can be
achieve by electrolysis of soluble thallium salts.
192
Reactions
Reaction of thallium with air
Freshy cut thallium tarnishes slowly to give a grey oxide film that protects the
remaining metal from further oxidation. When heated strongly to red heat in air,
poisonous thallium(I) oxide is formed.
2Tl(s) + O2(g) → Tl2O(s)
Reaction of thallium with water
Thallium seems not to react with air-free water. Thallium metal tarnishes slowly in
moist air or dissolves in water to give poisonous thallium(I) hydroxide.
2Tl(s) + 2H2O(l) → 2TlOH(aq) + H2(g)
Reaction of thallium with the halogens
Thallium metal reacts vigorously with fluorine, F2, chlorine, Cl2, and bromine, Br2, to
form the dihalides thallium(III) fluoride, TlF3, thallium(III) chloride, TlCl3, tand
hallium(III) bromide, TlBr3, respectively. All these compounds are poisonous.
2Tl(s) + 3F2(g) → 2TlF3(s) []
2Tl(s) + 3Cl2(g) → 2TlCl3(s) []
2Tl(s) + 3Br2(l) → 2TlBr3(s) []
Reaction of thallium with acids
Thallium dissolves only slowly in sulphuric acid, H2SO4, or hydrochloric acid, HCl,
because the poisonous thallium(I) salts produced are not very soluble.
193
ELEMENTS OF GROUP III B
SCANDIUM (Sc)
Physic, chemical, and atomic properties
1. Name : Scandium
2. Symbol : Sc
3. Atomic number : 21
4. Atomic weight : 44.9559
5. Atomic radius : 160.6 pm
6. Standard state : Solid at 298 K
7. Melting point : 15410C
8. Boiling Point : 28360C
9. Liquid range : 1289 K
10.Group in periodic table : 3
194
11.Period in periodic table : 4
12.Block in periodic table : d-block
13.Electron configuration : [Ar]4s23d1
14.Oxidation States : 3
15.Colour : silvery white
16.classification : Metallic
Electronegativities
The most used definition of electronegativity is that an element's
electronegativity is the power of an atom when in a molecule to attract electron
density to itself. The electronegativity depends upon a number of factors and in
particuler as the other atoms in the molecule. The first scale of electronegativity
was developed by Linus Pauling and on his scale scandium has a value of 1.36 on a
scale running from from about 0.7 (an estimate for francium) to 2.20 (for hydrogen)
to 3.98 (fluorine). Electronegativity has no units but "Pauling units" are often used
when indicating values mapped on to the Pauling scale. On the interactive plot
below you may find the "Ball chart" and "Shaded table" styles most useful. There
are a number of ways to produce a set of numbers representing electronegativity
and five are given in the table above. The Pauling scale is perhaps the most famous
and suffices for many purposes.
Electronic configuration
The following represents the electronic configuration and its associated term
symbol for the ground state neutral gaseous atom. The configuration associated
with scandium in its compounds is not necessarily the same.
Ground state electron configuration : [Ar].3d1.4s2
Shell structure : 2.8.9.2
Term symbol : 2D3/2
195
One measure of size is the element-element distance within the element. The
bond length in ScSc is: 321.2 pm. It is not always easy to make sensible
comparisons between the elements however as some bonds are quite short
because of multiple bonding (for instance the O=O distance in O2 is short because
of the the double bond connecting the two atoms. There are several other ways
ways to define radius for atoms and ions. Follow the appropriate hyperlinks for
literature references and definitions of each type of radius. All values of radii are
given in picometres (pm). Conversion factors are:
1 pm = 1 x 10-12 metre (meter)
100 pm = 1 Ångstrom
1000 pm = 1 nanometre (nm, nanometer)
Discovery
(L. Scandia: Scandinavia) On the basis of the Periodic System, Mendeleev
predicted the existence of ekaboron, which would have an atomic weight between
40 of calcium and 48 of titanium.
Scandium was discovered by Lars Fredrik Nilson at Sweden. Origin of name
from the Latin word “Scandia” meaning “Scandinavia”.
The element was discovered by Nilson in 1878 in the minerals euxenite and
gadolinite, which had not yet been found anywhere except in Scandinavia. He and
his coworkers were actually looking for rare earth metals. By processing 10 kg of
euxenite and other residues of rare-earth minerals, Nilson was able to prepare
about 2g of highly pure scandium oxide (scandia, Sc2O3) of high purity. Later
scientists pointed out that Nilson's scandium was identical with Mendeleev's
ekaboron.
196
In 1871 Mendeleev predicted that an element should exist that would
resemble boron in its properties. He therefore called it ekaboron, (symbol Eb). Per
Theodor Cleave found scandium oxide at about the same time. He noted that the
new element was the element ekaboron predicted by Mendeleev in 1871.
Appearance
Scandium is a silver-white metal which develops a slightly yellowish or
pinkish cast upon exposure to air. A relatively soft element, scandium resembles
yttrium and the rare-earth metals more than it resembles aluminum or titanium. It
is a very light metal and has a much higher melting point than aluminum, making it
of interest to designers of spacecraft. Scandium is not attacked by a 1:1 mixture of
HNO3 and 48% HF. Scandium reacts repidly with many acids. Scandium is
apparently a much more abundant element in the sun and certain stars than on
eart.
Source
Scandium is apparently much more abundant (the 23rd most) in the sun and
certain stars than on earth (the 50th most abundant). It is widely distributed on
earth, occurring in very minute quantities in over 800 mineral species. The blue
color of beryl (aquamarine variety) is said to be due to scandium. It occurs as a
principal component in the rare mineral thortveitite, found in Scandinavia and
Malagasy. It is also found in the residues remaining after the extraction of tungsten
from Zinnwald wolframite, and in wiikite and bazzite.
Most scandium is presently being recovered from thortveitite or is extracted
as a by-product from uranium mill tailings. Metallic scandium was first prepared in
1937 by Fischer, Brunger, and Grienelaus who electrolyzed a eutectic melt of
potassium, lithium, and scandium chlorides at 700 to 800oC. Tungsten wire and a
pool of molten zinc served as the electrodes in a graphite crucible. Pure scandium is
now produced by reducing scandium fluoride with calcium metal.
The production of the first pound of 99% pure scandium metal was
announced in 1960.
Uses
197
The following uses for scandium are gathered from a number of sources as well
as from anecdotal comments. I'd be delighted to receive corrections as well as
additional referenced uses (please use the feedback mechanism to add uses).
isotope tracing in crude oil analysis
the iodide added to mercury vapour lamps and produces a highly efficient
light source resembling sunlight, which is important for indoor or night-time
colour TV transmission.
apparently scandium is a component of alloys used to make metallic baseball
bats (mercifully metallic cricket bats were banned after Dennis Lillee tried to
use one).
About 20 kg of scandium (as Sc2O3) are used yearly in the U.S. to produce
high-intensity lights. The radioactive isotope 46Sc is used as a tracing agent in
refinery crackers for crude oil, etc.
Scandium iodide added to mercury vapor lamps produces a highly efficient
light source resembling sunlight, which is important for indoor or night-time color
TV.
Isolation
Isolation: preparation of metallic samples of scandium is not normally
necessary given that it is commercially avaialable. In practice littel scandium is
produced. The mineral thortveitite contains 35-40% Sc2O3 is used to produce
scandium metal but another important source is as a byproduct from uranium ore
processing, even though these only contain 0.02% Sc2O3 .
Handling
Little is yet known about the toxicity of scandium, therefore it should be handled
with care.
Reactions
Reaction of scandium with air
198
Scandium metal tarnishes in air and burns readily to form scandium (III) oxide,
Sc2O3.
4Sc + 3O2 → 2Sc2O3
Reaction of scandium with water
When finely divided, or heated, scandium metal dissolves in water to form solutions
containing the aquated Sc(III) ion together with hydrogen gas, H2.
2Sc(s) + 6H2O(aq) → 2Sc3+(aq) + 6OH-(aq) + 3H2(g)
Reaction of scandium with the halogens
Scandium is very reactive towards the halogens fluorine, F2, chlorine, Cl2 bromine,
Br2, and iodine, I2, and burns to form the trihalides scandium(III) fluoride, ScF3 ,
scandium(III) chloride, ScCl3, scandium(III) bromide, ScBr3, and scandium(III) iodide,
ScI3 respectively.
2Sc(s) + 3F2(g) → 2ScF3(s)
2Sc(s) + 3Cl2(g) → 2ScCl3(s)
2Sc(s) + 3Br2(g) → 2ScBr3(s)
2Sc(s) + 3I2(g) → 2ScI3(s)
Reaction of scandium with acids
Scandium metal dissolves readily in dilute hydrochloric acid to form solutions
containing the aquated Sc(III) ion together with hydrogen gas, H2.
2Sc(s) + 6HCl(aq) → 2Sc3+(aq) + 6Cl-(aq) + 3H2(g)
YTTRIUM (Y)
199
Physic, chemical, and atomic properties
1. Name : Yttrium
2. Symbol : Y
3. Atomic number : 39
4. Atomic weight : 88.9059
5. Atomic radius : 181 pm
6. Standard state : solid at 298 K
7. Melting point : 15220C
8. Boiling Point : 33450C
9. Group in periodic table : 3
10.Period in periodic table : 5
11.Block in periodic table : d-block
12.Electron configuration : [Kr]5s14d1
13.Oxidation States : 3
14.Relative Atomic Mass : 88.91
15.Liquid range : 1810 K
Electronegativities
The most used definition of electronegativity is that an element's
electronegativity is the power of an atom when in a molecule to attract electron
density to itself. The electronegativity depends upon a number of factors and in
particuler as the other atoms in the molecule. The first scale of electronegativity
was developed by Linus Pauling and on his scale yttrium has a value of 1.22 on a
scale running from from about 0.7 (an estimate for francium) to 2.20 (for hydrogen)
to 3.98 (fluorine). Electronegativity has no units but "Pauling units" are often used
when indicating values mapped on to the Pauling scale. On the interactive plot
below you may find the "Ball chart" and "Shaded table" styles most useful.
200
Electronic configuration
The following represents the electronic configuration and its associated term
symbol for the ground state neutral gaseous atom. The configuration associated
with yttrium in its compounds is not necessarily the same.
Ground state electron configuration : [Kr].4d1.5s2
Shell structure : 2.8.18.9.2
Term symbol : 2D3/2
A schematic representation of the shell structure of yttrium - not what the atom of
yttrium "looks like".
One measure of size is the element-element distance within the element. The bond
length in YY is: 355.1 pm. It is not always easy to make sensible comparisons
between the elements however as some bonds are quite short because of multiple
bonding (for instance the O=O distance in O2 is short because of the the double
bond connecting the two atoms.
There are several other ways ways to define radius for atoms and ions. Follow the
appropriate hyperlinks for literature references and definitions of each type of
radius. All values of radii are given in picometres (pm). Conversion factors are:
1 pm = 1 x 10-12 metre (meter)
100 pm = 1 Ångstrom
1000 pm = 1 nanometre (nm, nanometer)
Discovery
201
Yettrium was discovered by Johann Gadolin at 1794 in Finland. Origin of name
: after the village of “Ytterby” near Vaxholm in Sweden.
Yttria (yttrium oxide, Y2O3) was discovered by Gadolin in 1794 in a mineral
called gadolinite from Yetterby. Ytterby is the site of a quarry which contains many
unusual minerals containing erbium, terbium, and ytterbium as well as yttrium.
Fredrich Wohler obtained the impure element in 1828 by reduction of the anhydrous
chlorida (YCl3) with patassium.
In 1843 Mosander showed that yttira could be resolved into the oxides (or
earths) of three elements. The name yttria was reserved for the most basic one; the
others were named erbia and terbia
Appearance
Yttrium has a silver-metallic luster and is relatively stable in air. Turnings of
the metal, however, ignite in air if their temperature exceeds 400oC. Finely divided
yttrium is very unstable in air. Yttrium is found in most rare earth minerals. Moon
rocks contain yttrium is uses as a “phosphor” to produce the red colour in television
screens.
Source
Yttrium occurs in nearly all of the rare-earth minerals. Analysis of lunar rock
samples obtained during the Apollo missions show a relatively high yttrium content.
It is recovered commercially from monazite sand, which contains about 3%, and
from bastnasite, which contains about 0.2%. Wohler obtained the impure element in
1828 by reduction of the anhydrous chloride with potassium. The metal is now
produced commercially by reduction of the fluoride with calcium metal. It can also
be prepared by other techniques.
Uses
Yttrium oxide is one of the most important compounds of yttrium and
accounts for the largest use. It is widely used in making YVO4 europium, and Y2O3
europium phosphors to give the red color in color television tubes. Hundreds of
thousands of pounds are now used in this application.
Yttrium oxide also is used to produce yttrium-iron-garnets, which are very
effective microwave filters.
202
Yttrium iron, aluminum, and gadolinium garnets, with formulas such as
Y3Fe5O12 and Y3Al5O12, have interesting magnetic properties. Yttrium iron garnet is
also exceptionally efficient as both a transmitter and transducer of acoustic energy.
Yttrium aluminum garnet, with a hardness of 8.5, is also finding use as a gemstone
(simulated diamond).
Small amounts of yttrium (0.1 to 0.2%) can be used to reduce the grain size
in chromium, molybdenum, zirconium, and titanium, and to increase strength of
aluminum and magnesium alloys. Alloys with other useful properties can be
obtained by using yttrium as an additive. The metal can be used as a deoxidizer for
vanadium and other nonferrous metals. The metal has a low cross section for
nuclear capture. 90Y, one of the isotopes of yttrium, exists in equilibrium with its
parent 90Sr, a product of nuclear explosions. Yttrium has been considered for use as
a nodulizer for producing nodular cast iron, in which the graphite forms compact
nodules instead of the usual flakes. Such iron has increased ductility.
Yttrium also can be used in laser systems and as a catalyst for ethylene
polymerization reactions. It also has potential use in ceramic and glass formulas, as
the oxide has a high melting point and imparts shock resistance and low expansion
characteristics to glass.
The following uses for yttrium are gathered from a number of sources as well
as from anecdotal comments. I'd be delighted to receive corrections as well as
additional referenced uses (please use the feedback mechanism to add uses).
YVO4 europium, and Y203 europium phosphors give the red colour in colour
television tubes
the oxide is used to produce yttrium-iron-garnets, which are very effective
microwave filters
yttrium iron, aluminum, and gadolinium garnets have interesting magnetic
properties. Yttrium iron garnet is also exceptionally efficient as both a
transmitter and transducer of acoustic energy
yttrium aluminium garnet is a gemstone (simulated diamond)
used in laser systems
used as a catalyst for ethene polymerization
203
potential use in ceramic and glasses as the oxide has a high melting point
and imparts shock resistance and low expansion characteristics to glass
increases increase the strengths of alloys of metals such as chromium,
aluminium, and magnesium.
Isolation
Isolation: yttrium metal is available commercially so it is not normally
necesary to make it in the laboratory. Yttrium is found in lathanoid minerals and the
extraction of the yttrium and the lanthanoid metals from the ores is highly complex.
Initially, the metals are extractedas salts from the ores by extraction with sulphuric
acid (H2SO4), hydrochloric acid (HCl), and sodium hydroxide (NaOH). Modern
purification techniques for these lanthanoid salt mixtures involve selective
complexation techniques, solvent extractions, and ion exchange chromatography.
Pure yttrium is available through the reduction of YF3 with calcium metal.
2YF3 + 3Ca → 2Y + 3CaF2
Reactions
Reaction of yttrium with air
Yttrium metal tarnishes slowly in air and burns readily to form yttrium (III) oxide,
Y2O3.
4Y + 3O2 → 2Y2O3
Reaction of yttrium with water
When finely divided, or heated, yttrium metal dissolves in water to form solutions
containing the aquated Y(III) ion together with hydrogen gas, H2.
2Y(s) + 6H2O(aq) → 2Y3+(aq) + 6OH-(aq) + 3H2(g)
Reaction of yttrium with the halogens
204
Yttrium is very reactive towards the halogens fluorine, F2, chlorine, Cl2 bromine, Br2,
and iodine, I2, and burns to form the trihalides yttrium(III) fluoride, YF3 , yttrium(III)
chloride, YCl3, yttrium(III) bromide, YBr3, and yttrium(III) iodide, YI3 respectively.
2Y(s) + 3F2(g) → 2YF3(s)
2Y(s) + 3Cl2(g) → 2YCl3(s)
2Y(s) + 3Br2(g) → 2YBr3(s)
2Y(s) + 3I2(g) → 2YI3(s)
Reaction of yttrium with acids
Yttrium metal dissolves readily in dilute hydrochloric acid to form solutions
containing the aquated Y(III) ion together with hydrogen gas, H2.
2Y(s) + 6HCl(aq) → 2Y3+(aq) + 6Cl-(aq) + 3H2(g)
LANTHANUM (La)
Physic, chemical, and atomic properties
205
1. Name : Lanthanum
2. Symbol : La
3. Atomic number : 57
4. Atomic weight : 138.9055
5. Atomic radius : 187.7 pm
6. Melting point : 9180C
7. Boiling Point : 34640C
8. Standard state : solid at 298 K
9. Liquid range : 2550 K
10.Period in periodic table : 6
11.Block in periodic table : f-block
12.Electron configuration : [Xe]6s25d1
13.Oxidation States : 2
14.Relative Atomic Mass : 139
15.Relative Density : 6.146
16.Colour : silvery white
17.Classification : Metallic
Electronegativitie
The most used definition of electronegativity is that an element's
electronegativity is the power of an atom when in a molecule to attract electron
density to itself. The electronegativity depends upon a number of factors and in
particuler as the other atoms in the molecule. The first scale of electronegativity
was developed by Linus Pauling and on his scale lanthanum has a value of 1.10 on a
scale running from from about 0.7 (an estimate for francium) to 2.20 (for hydrogen)
to 3.98 (fluorine). Electronegativity has no units but "Pauling units" are often used
when indicating values mapped on to the Pauling scale. On the interactive plot
below you may find the "Ball chart" and "Shaded table" styles most useful.
Electronic configuration
206
The following represents the electronic configuration and its associated term
symbol for the ground state neutral gaseous atom. The configuration associated
with lanthanum in its compounds is not necessarily the same.
Ground state electron configuration : [Xe].5d1.6s2
Shell structure : 2.8.18.18.9.2
Term symbol : 2D3/2
A schematic representation of the shell structure of lanthanum - not what the atom
of lanthanum "looks like". One measure of size is the element-element distance
within the element. The bond length in LaLa is: 373.9 pm. It is not always easy to
make sensible comparisons between the elements however as some bonds are
quite short because of multiple bonding (for instance the O=O distance in O 2 is
short because of the the double bond connecting the two atoms.
There are several other ways ways to define radius for atoms and ions. Follow the
appropriate hyperlinks for literature references and definitions of each type of
radius. All values of radii are given in picometres (pm). Conversion factors are:
1 pm = 1 x 10-12 metre (meter)
100 pm = 1 Ångstrom
1000 pm = 1 nanometre (nm, nanometer)
Discovery
Lanthanum was discovered by Carl Gustaf Mosander at 1839 in Sweden.
Origin of name: from the Greek word "lanthanein" meaning "to lie hidden". Carl
Gustav Mosander recognized the element lanthanum in impure cerium nitrate in
1839. His extraction resulted in the oxide lanthana (La2O3). A number of other
207
lanthanides (rare-earths) were later discovered by identification of the impurities in
yttrium and cerium compounds. (Greek lanthanein: to lie hidden) Mosander in 1839
extracted lanthana from impure cerium nitrate and recognized the new element.
Lanthanum was isolated in relatively pure form in 1923. Iron exchange and solvent
extraction techniques have led to much easier isolation of the so-called "rare-earth"
elements.
Appearance
Lanthanum is silvery white, malleable, ductile, and soft enough to be cut with
a knife. It is one of the most reactive of the rare-earth metals. It oxidizes rapidly
when exposed to air. Cold water attacks lanthanum slowly, while hot water attacks
it much more rapidly.
The metal reacts directly with elemental carbon, nitrogen, boron, selenium, silicon,
phosphorus, sulfur, and with halogens. At 310 C, lanthanum changes from a
hexagonal to a face-centered cubic structure, and at 865 C it again transforms into
a body-centered cubic structure. Pure metal lutetium has been isolated only in
recent years and is one of the more difficult to prepare. It can be prepared by the
reduction of anhydrous LuCl3 or LuF3 by an alkali or alkaline earth metal. The metal
is silvery white and relatively stable in air. It is a rare earth metal and perhaps the
most expensive of all rare elements. It is found in small amounts with all rare earth
metals, and is very difficult to separate from other rare elements.
Source
Lanthanum is found in rare-earth minerals such as cerite, monazite, allanite,
and bastnasite. Monazite and bastnasite are principal ores in which lanthanum
occurs in percentages up to 25 percent and 38 percent respectively. Misch metal,
used in making lighter flints, contains about 25 percent lanthanum.
The availability of lanthanum and other rare earths has improved greatly in
recent years. The metal can be produced by reducing the anhydrous fluoride with
calcium .
Uses
208
Rare-earth compounds containing lanthanum are extensively used in carbon
lighting applications, especially by the motion picture industry for studio lighting
and projection. This application consumes about 25 percent of the rare-earth
compounds produced. La2O3 improves the alkali resistance of glass, and is used in
making special optical glasses. Small amounts of lanthanum, as an additive, can be
used to produce nodular cast iron.
There is current interest in hydrogen sponge alloys containing lanthanum.
These alloys take up to 400 times their own volume of hydrogen gas, and the
process is reversible. Every time they take up the gas, heat energy is released;
therefore these alloys have possibilities in an energy conservation system.
The following uses for lanthanum are gathered from a number of sources as
well as from anecdotal comments. I'd be delighted to receive corrections as well as
additional referenced uses (please use the feedback mechanism to add uses).
rare-earth compounds containing lanthanum are extensively used in carbon
lighting applications, especially by the motion picture industry for studio
lighting and projection
203La improves the alkali resistance of glass, and is used in making special
optical glasses
small amounts as an additive are used to produce nodular cast iron
hydrogen sponge alloys containing lanthanum reversibly take up to 400
times their own volume of hydrogen gas. Heat is released, therefore these
alloys have potential in energy conservation systems
lighter flints
alloys
Handing
Lanthanum and its compounds have a low to moderate acute toxicity rating;
therefore, care should be taken in handling them.
Isolation
209
Isolation: lanthanum metal is available commercially so it is not normally
necessary to make it in the laboratory, which is just as well as it is difficult to
separate it from as the pure metal. This is largely because of the way it is found in
nature. The lanthanoids are found in nature in a number of minerals. The most
important are xenotime, monazite, and bastnaesite. The first two are
orthophosphate minerals LnPO4 (Ln deonotes a mixture of all the lanthanoids except
promethium which is vanishingly rare) and the third is a fluoride carbonate LnCO3F.
Lanthanoids with even atomic numbers are more common. The most comon
lanthanoids in these minerals are, in order, cerium, lanthanum, neodymium, and
praseodymium. Monazite also contains thorium and ytrrium which makes handling
difficult since thorium and its decomposition products are radioactive.
For many purposes it is not particularly necessary to separate the metals, but
if separation into individual metals is required, the process is complex. Initially, the
metals are extracted as salts from the ores by extraction with sulphuric acid
(H2SO4), hydrochloric acid (HCl), and sodium hydroxide (NaOH). Modern purification
techniques for these lanthanoid salt mixtures are ingenious and involve selective
complexation techniques, solvent extractions, and ion exchange chromatography.
Pure lanthanum is available through the reduction of LaF3 with calcium metal.
2LaF3 + 3Ca → 2La + 3CaF2
This would work for the other calcium halides as well but the product CaF2 is
easier to handle under the reaction conditions (heat to 50°C above the melting
point of the element in an argon atmosphere). Excess calcium is removed from the
reaction mixture under vacuum.
Reactions
Reaction of lanthanum with air
Lanthanum metal tarnishes slowly in air and burns readily to form lanthanum (III)
oxide, La2O3.
4La + 3O2 → 2La2O3
Reaction of lanthanum with water
210
The silvery white metal lanthanum is quite electropositive and reacts slowly with
cold water and quite quickly with hot water to form lanthanum hydroxide, La(OH)3,
and hydrogen gas (H2).
2La(s) + 6H2O(g) → 2La(OH)3(aq) + 3H2(g)
Reaction of lanthanum with the halogens
Lanthanum metal reacts with all the halogens to form lanthanum(III) halides. So, it
reacts with fluorine, F2, chlorine, Cl2, bromine, I2, and iodine, I2, to form respectively
lanthanum(III) bromide, LaF3, lanthanum(III) chloride, LaCl3, lanthanum(III) bromide,
LaBr3, and lanthanum(III) iodide, LaI3.
2La(s) + 3F2(g) → 2LaF3(s)
2La(s) + 3Cl2(g) → 2LaCl3(s)
2La(s) + 3Br2(g) → 2LaBr3(s)
2La(s) + 3I2(g) → 2LaI3(s)
Reaction of lanthanum with acids
Lanthanum metal dissolves readily in dilute sulphuric acid to form solutions
containing the aquated La(III) ion together with hydrogen gas, H2. It is quite likely
that La3+(aq) exists as largely the complex ion [La(OH2)9]3+
2La(s) + 3H2SO4(aq) → 2La3+(aq) + 3SO42-(aq) + 3H2(g)
211
ACTINIUM (Ac)
Physical Information
1. Name : Actinium
2. Symbol : Ac
3. Atomic number : 89
4. Atomic weight : 227
5. Atomic radius : 187,8 pm
6. Melting point : 1051
7. Boiling Point : 3159
8. Liquid range : 2250 K
212
9. Standard state : solid at 298 K
10.Group name : Actinoid
11.Period in periodic table : 7 (actinoid)
12.Block in periodic table : f-block
13.Electron configuration : [Rn]7s26d1
14.Oxidation States : 3
15.Relative Atomic Mass : 227 (approximately)
16.Relative Density : 10
17.Colour : silvery
18.Classification : Metallic
Electronegativities
The most used definition of electronegativity is that an element's
electronegativity is the power of an atom when in a molecule to attract electron
density to itself. The electronegativity depends upon a number of factors and in
particuler as the other atoms in the molecule. The first scale of electronegativity
was developed by Linus Pauling and on his scale actinium has a value of 1.1 on a
scale running from from about 0.7 (an estimate for francium) to 2.20 (for hydrogen)
to 3.98 (fluorine). Electronegativity has no units but "Pauling units" are often used
when indicating values mapped on to the Pauling scale. On the interactive plot
below you may find the "Ball chart" and "Shaded table" styles most useful.
Electronic Configuration
The following represents the electronic configuration and its associated term
symbol for the ground state neutral gaseous atom. The configuration associated
with actinium in its compounds is not necessarily the same.
Ground state electron configuration : [Rn].6d1.7s2
Shell structure : 2.8.18.32.18.9.2
Term symbol : 2D3/2
213
One measure of size is the element-element distance within the element. The bond
length in AcAc is: 375.6 pm. It is not always easy to make sensible comparisons
between the elements however as some bonds are quite short because of multiple
bonding (for instance the O=O distance in O2 is short because of the the double
bond connecting the two atoms. There are several other ways ways to define radius
for atoms and ions. Follow the appropriate hyperlinks for literature references and
definitions of each type of radius. All values of radii are given in picometres (pm).
Conversion factors are:
1 pm = 1 x 10-12 metre (meter)
100 pm = 1 Ångstrom
1000 pm = 1 nanometre (nm, nanometer)
Discovery
Actinium, named from the Greek aktinos (ray) is a rare, extremely radioactive
metal that glows in the dark (the photo shown above is of Ac2O3). Discovered by
Andre Debierne in 1899 in France and independently by F. Giesel in 1902, both of
whom obtained it while working on separation techniques for rare eart oxides.
Occurs naturally in association with uranium minerals.
Appearance
Actinium-227, a decay product of uranium-235, is a beta emitter with a 21.6-
year half-life. Its principal decay products are thorium-227 (18.5-day half-life),
radium-223 (11.4-day half-life), and a number of short-lived products including
radon, bismuth, polonium, and lead isotopes. In equilibrium with its decay products,
it is a powerful source of alpha rays. Actinium metal has been prepared by the
reduction of actinium fluoride with lithium vapor at about 1100 to 1300-degrees C.
The chemical behavior of actinium is similar to that of the rare earths, particularly
214
lanthanum. Purified actinium comes into equilibrium with its decay products at the
end of 185 days, and then decays according to its 21.6-year half-life. It is about 150
times as active as radium, making it of value in the production of neutrons.
Source
Actinium occurs naturally in uranium minerals. It is made by the neutron
bombardment of the radium isotope 228Ra.
Uses
Actinium is used as a source of Neutrons. The following uses for actinium are
gathered from a number of sources as well as from anecdotal comments. I'd be
delighted to receive corrections as well as additional referenced uses (please use
the feedback mechanism to add uses).
thermoelectric power
source of neutrons
General Information
Actinium occurs in association with Uranium ores, as a decay product of Uranium-
235.
It has three Isotopes
nuclide : 225Ac 227Ac 228Ac
atomic mass : 227.03
natural abundance : 0% trace trace
half-life : 10 days 21.6 yrs 6.13 h
Actinium 227, which has a half-life of 22 years, is formed by the irradiation of
Radium.
215
Reference
http://www.ucc.ie/academic/chem/dolchem/html/elem/group.html kamis 23 September 2010. pkl.18:16
http://www.periodic.lanl.gov/elements/89.html kamis 23 September 10.pkl.18:16
http://www.webelements.com/index.html kamis 23 September 2010 pkl 18.17
http://www.britannica.com/EBchecked/topic/74395/boron-group-element Primary Contributor: Alan Gibbs Massey Rabu 22 September 2010 pkl. 13.16
http://www.lenntech.com/periodic/elements/al.htm#ixzz10KRFTEVJ Rabu 22 september 2010 pukul 14.13
216
CHAPTER I
INTRODUCTION
In periodicity, there are many elements that classification based on its properties. For example are metal and non metal. The elements are classification into groups and period. Periodicity has 144 elements with 16 groups (8 groups A and 8 groups B), Aktanida and Lantanida.
This paper will discuss about elements in groups VA and VB. Groups VA consist of Nitrogen, Phospor, Arsenic, Antimony , and Bismut. Groups VB consist of Vanadium, Niobium, Tantalum, and Dubnium.
The elements in group VA and VB has application in daily activity. Nitrogen has use for freeze. Phospor uses for toxic of rat and makes alloy. Bismut uses for makes tender iron, and catalyst for make akrilat fiber. Antanium(Sb) uses as semiconductor and batere. Arsen as additive of Ge and Si.
Vanadium used in nuclear reactors. Niobium used in surgical implants because they do not react with human tissue. Tantalum resists corrosion and is almost impervious to chemical attack.
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CHAPTER II
MATTER
2.1. Elements of group VA
VA group consists of five elements, namely Nitrogen, Phospor, Bismut, Antimony, and Arsen. Some properties of the elements of this group we can see in the table bellow :
Properties Nitrogen Phospor Arsen Antimony Bismut
Atomic number
7 15 33 51 83
Atomic mass14.0067 g.mol -1
30.973762 g.mol
-1
74.9216 g.mol -1
121.75 g.mol -1
208.98040
g.mol -1
Electronegativity according to Pauling
3.0 2.19 2.01.9 2.02
Density1.25*10-3
g.cm-3 at 20°C
1.823, 2.2–2.34, 2.36, 2.69 g·cm −3
5.7 g.cm-3 at 14°C
6.684 g.cm-3 9.78 g·cm −3
Melting point -210 °C44.2 °C, 610 °C
814 °C (36 atm)
631 °C
544.7 K271.5 ° ,C520.7
° ,F
Boiling point-195.8
°C280.5 °C
615 °C (sublimation)
1380 °C
1837 K, 1564 °C, 2847 °F
Vanderwaals radius
0.092 nm
180 pm 0.139 nm
0.159 nm 207 pm
Ionic radius
0.171 nm (-3) ;
0.011 (+5) ; 0.016 (+3)
-0.222 nm (-2) 0,047 nm (+5) 0,058 (+3)
0.245 nm (-3); 0.062 nm (+5); 0.076
nm (+3)
-
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Electronic shell[He]2s22
p3
[Ne]
3s2 3p3[ Ar ] 3d10 4s2 4p3
[ Kr ] 4d10
5s25p3
[Xe]4f145d10
6s26p3
Energy of first ionisation
1402 kJ.mol -1
1011.8 kJ·mol −1 947 kJ.mol -1
834 kJ.mol -1 703 kJ·mol −1
Energy of second ionisation
2856 kJ.mol -1
1907 kJ·mol−1 1798 kJ.mol -
11595 kJ.mol -1
1610 kJ·mol−1
Energy of third ionisation
4578 kJ.mol -1
2914.1 kJ·mol−1 2736 kJ.mol -
12443 kJ.mol -1
2466 kJ·mol−1
2.1.1. Nitrogen
Nitrogen (pronounced) is a chemical element that has the symbol N, atomic number of 7 and atomic mass 14.00674 u. Elemental nitrogen is a colorless, odorless, tasteless and mostly inert diatomic gas at standard conditions, constituting 78.08% by volume of Earth's atmosphere.
Many industrially important compounds, such as ammonia, nitric acid, organic nitrates (propellants and explosives), and cyanides, contain nitrogen. The extremely strong bond in elemental nitrogen dominates nitrogen chemistry, causing difficulty for both organisms and industry in breaking the bond to convert the N2 into useful compounds, but releasing large amounts of often useful energy, when these compounds burn, explode, or decay back into nitrogen gas.
The element nitrogen was discovered by Scottish physician Daniel Rutherford in 1772. Nitrogen occurs in all living organisms. It is a constituent element of amino acids and thus of proteins, and of nucleic acids (DNA and RNA). It resides in the chemical structure of almost all neurotransmitters, and is a defining component of alkaloids, biological molecules produced by many organisms.
1. History
Nitrogen is formally considered to have been discovered by Daniel Rutherford in 1772, who called it noxious air or fixed air. That there was a fraction of air that did not support combustion was well-known to the late 18th century chemist. Nitrogen was also studied at about the same time by Carl Wilhelm Scheele, Henry Cavendish, and
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Joseph Priestley, who referred to it as burnt air or phlogisticated air. Nitrogen gas was inert enough that Antoine Lavoisier referred to it as "mephitic air" or azote, from the Greek word (azotos) meaning "lifeless".Animals died in it, and it was the principal component of air in which animals had suffocated and flames had burned to extinction. Lavoisier's name for nitrogen is used in many languages (French, Russian, etc.) and still remains in English in the common names of many compounds, such as hydrazine and compounds of the azide ion. Compounds of nitrogen were known in the Middle Ages.
The alchemists knew nitric acid as aqua fortis (strong water). The mixture of nitric and hydrochloric acids was known as aqua regia (royal water), celebrated for its ability to dissolve gold (the king of metals). The earliest military, industrial and agricultural applications of nitrogen compounds involved uses of saltpeter (sodium nitrate or potassium nitrate), notably in gunpowder, and later as fertilizer. In 1910, Lord Rayleigh discovered that an electrical discharge in nitrogen gas produced "active nitrogen", an allotrope considered to be monatomic. The "whirling cloud of brilliant yellow light" produced by his apparatus reacted with quicksilver to produce explosive mercury nitride.
2. Properties
Nitrogen is a nonmetal, with an electronegativity of 3.04. It has five electrons in its outer shell and is therefore trivalent in most compounds. The triple bond in molecular nitrogen (N2) is the strongest. The resulting difficulty of converting N2 into other compounds, and the ease (and associated high energy release) of converting nitrogen compounds into elemental N2, have dominated the role of nitrogen in both nature and human economic activities.
At atmospheric pressure molecular nitrogen condenses (liquefies) at 77 K (−195.8 °C) and freezes at 63 K (−210.0 °C) into the beta hexagonal close-packed crystal allotropic form. Below 35.4 K (−237.6 °C) nitrogen assumes the alpha cubic crystal allotropic form. Liquid nitrogen, a fluid resembling water in appearance, but with 80.8% of the density (the density of liquid nitrogen at its boiling point is 0.808 g/mL), is a common cryogen.
Unstable allotropes of nitrogen consisting of more than two nitrogen atoms have been produced in the laboratory, like N3 and N4. Under extremely high pressures (1.1 million atm) and high temperatures (2000 K), as produced using a diamond anvil cell,
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nitrogen polymerizes into the single-bonded cubic gauche crystal structure. This structure is similar to that of diamond, and both have extremely strong covalent bonds. N4 is nicknamed "nitrogen diamond.
a. Isotopes
There are two stable isotopes of nitrogen: 14N and 15N. By far the most common is 14N (99.634%), which is produced in the CNO cycle in stars. Of the ten isotopes produced synthetically, 13N has a half-life of ten minutes and the remaining isotopes have half-lives on the order of seconds or less. Biologically mediated reactions (e.g., assimilation, nitrification, and denitrification) strongly control nitrogen dynamics in the soil. These reactions typically result in 15N enrichment of the substrate and depletion of the product.
A small part (0.73%) of the molecular nitrogen in Earth's atmosphere is the isotopologue 14N15N, and almost all the rest is 14N2.
Radioisotope 16N is the dominant radionuclide in the coolant of pressurized water reactors during normal operation. It is produced from 16O (in water) via (n,p) reaction. It has a short half-life of about 7.1 s, but during its decay back to 16O produces high-energy gamma radiation (5 to 7 MeV). Because of this, the access to the primary coolant piping must be restricted during reactor power operation. 16N is one of the main means used to immediately detect even small leaks from the primary coolant to the secondary steam cycle.
Electromagnetic spectrum:
A 1×5 cm vial of glowing ultrapure nitrogen Nitrogen discharge (spectrum) tube.
Molecular nitrogen (14N2) is largely transparent to infrared and visible radiation because it is a homonuclear molecule and thus has no dipole moment to couple to electromagnetic radiation at these wavelengths. Significant absorption occurs at extreme ultraviolet wavelengths, beginning around 100 nanometers. This is associated with electronic transitions in the molecule to states in which charge is not distributed evenly between nitrogen atoms. Nitrogen absorption leads to significant absorption of ultraviolet radiation in the Earth's upper atmosphere and the atmospheres of other planetary bodies. For
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similar reasons, pure molecular nitrogen lasers typically emit light in the ultraviolet range.
Nitrogen also makes a contribution to visible air glow from the Earth's upper atmosphere, through electron impact excitation followed by emission. This visible blue air glow (seen in the polar aurora and in the re-entry glow of returning spacecraft) typically results not from molecular nitrogen, but rather from free nitrogen atoms combining with oxygen to form nitric oxide (NO).
b. Reactions
Structure of [Ru(NH3)5(N2)]2+.
Nitrogen is generally unreactive at standard temperature and pressure. N2 reacts spontaneously with few reagents, being resilient to acids and bases as well as oxidants and most reductants. When nitrogen reacts spontaneously with a reagent, the net transformation is often called nitrogen fixation.
Nitrogen reacts with elemental lithium. Lithium burns in an atmosphere of N2 to give lithium nitride:
6 Li + N2 → 2 Li3N
Magnesium also burns in nitrogen, forming magnesium nitride.
3 Mg + N2 → Mg3N2
N2 forms a variety of adducts with transition metals. The first example of a dinitrogen complex is [Ru(NH3)5(N2)]2+ (see figure at right). Such compounds are now numerous, other examples include IrCl(N2)(PPh3)2, W(N2)2(Ph2CH2CH2PPh2)2, and [(η5-C5Me4H)2Zr]2(μ2, η²,η²-N2). These complexes illustrate how N2 might bind to the metal(s) in nitrogenase and the catalyst for the Haber process. A catalytic process to reduce N2 to ammonia with the use of a molybdenum complex in the presence of a proton source was published in 2005. (See nitrogen fixation).
The starting point for industrial production of nitrogen compounds is the Haber process, in which nitrogen is fixed by reacting
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N2 and H2 over an iron(III) oxide (Fe3O4) catalyst at about 500 °C and 200 atmospheres pressure. Biological nitrogen fixation in free-living cyanobacteria and in the root nodules of plants also produces ammonia from molecular nitrogen. The reaction, which is the source of the bulk of nitrogen in the biosphere, is catalyzed by the nitrogenase enzyme complex which contains Fe and Mo atoms, using energy derived from hydrolysis of adenosine triphosphate (ATP) into adenosine diphosphate and inorganic phosphate (−20.5 kJ/mol).
3. Occurrence
Nitrogen is the largest single constituent of the Earth's atmosphere (78.082% by volume of dry air, 75.3% by weight in dry air). It is created by fusion processes in stars, and is estimated to be the 7th most abundant chemical element by mass in the universe.
Molecular nitrogen and nitrogen compounds have been detected in interstellar space by astronomers using the Far Ultraviolet Spectroscopic Explorer. Molecular nitrogen is a major constituent of the Saturnian moon Titan's thick atmosphere, and occurs in trace amounts in other planetary atmospheres.
Nitrogen is present in all living organisms, in proteins, nucleic acids and other molecules. It typically makes up around 4% of the dry weight of plant matter, and around 3% of the weight of the human body. It is a large component of animal waste (for example, guano), usually in the form of urea, uric acid, ammonium compounds and derivatives of these nitrogenous products, which are essential nutrients for all plants that cannot fix atmospheric nitrogen.
4. Applications
Liquid : Nitrogen has use for freeze.
Nitrogen occurs naturally in many minerals, such as saltpetre
(potassium nitrate), Chile saltpetre (sodium nitrate) and sal
ammoniac (ammonium chloride). Most of these are
uncommon, partly because of the minerals' ready solubility in
water. See also Nitrate minerals and Ammonium minerals.
2.1.2. Phospor
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1. History and discovery
The discovery of phosphorus is credited to the German alchemist Hennig Brand in 1669, although other chemists might have discovered phosphorus around the same time. Brand experimented with urine, which contains considerable quantities of dissolved phosphates from normal metabolism. Working in Hamburg, Brand attempted to create the fabled philosopher's stone through the distillation of some salts by evaporating urine, and in the process produced a white material that glowed in the dark and burned brilliantly. It was named phosphorus mirabilis ("miraculous bearer of light"). His process originally involved letting urine stand for days until it gave off a terrible smell. Then he boiled it down to a paste, heated this paste to a high temperature, and led the vapours through water, where he hoped they would condense to gold. Instead, he obtained a white, waxy substance that glowed in the dark. Brand had discovered phosphorus, the first element discovered since antiquity. We now know that Brand produced ammonium sodium hydrogen phosphate, (NH4)NaHPO4. While the quantities were essentially correct (it took about 1,100 L of urine to make about 60 g of phosphorus), it was unnecessary to allow the urine to rot. Later scientists would discover that fresh urine yielded the same amount of phosphorus.
Since that time, phosphors and phosphorescence were used loosely to describe substances that shine in the dark without burning. However, as mentioned above, even though the term phosphorescence was originally coined as a term by analogy with the glow from oxidation of elemental phosphorus, is now reserved for another fundamentally different process—re-emission of light after illumination.
Brand at first tried to keep the method secret,[24] but later sold the recipe for 200 thaler to D Krafft from Dresden,[4] who could now make it as well, and toured much of Europe with it, including England, where he met with Robert Boyle. The secret that it was made from urine leaked out and first Johann Kunckel (1630–1703) in Sweden (1678) and later Boyle in London (1680) also managed to make phosphorus. Boyle states that Krafft gave him no information as to the preparation of phosphorus other than that it was derived from "somewhat that belonged to the body of man". This gave Boyle a valuable clue, however, so that he, too, managed to make phosphorus, and published the method of its manufacture. Later he improved Brand's process by using sand in the reaction (still using urine as base material),
4 NaPO3 + 2 SiO2 + 10 C → 2 Na2SiO3 + 10 CO + P4
Robert Boyle was the first to use phosphorus to ignite sulfur-tipped wooden splints, forerunners of our modern matches, in 1680.
In 1769 Johan Gottlieb Gahn and Carl Wilhelm Scheele showed that calcium phosphate (Ca3(PO4)2) is found in bones, and they obtained phosphorus from bone ash. Antoine Lavoisier recognized phosphorus as an element in 1777. Bone ash was the major source of phosphorus until the 1840s. Phosphate rock, a mineral containing
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calcium phosphate, was first used in 1850 and following the introduction of the electric arc furnace in 1890, this became the only source of phosphorus. Phosphorus, phosphates and phosphoric acid are still obtained from phosphate rock. Phosphate rock is a major feedstock in the fertilizer industry.
2. Occurrence
Due to its reactivity with air and many other oxygen-containing substances, phosphorus is not found free in nature but it is widely distributed in many different minerals. Phosphate rock, which is partially made of apatite (an impure tri-calcium phosphate mineral), is an important commercial source of this element. About 50 percent of the global phosphorus reserves are in the Arab nations. Large deposits of apatite are located in China, Russia, Morocco, Florida, Idaho, Tennessee, Utah, and elsewhere. Albright and Wilson in the United Kingdom and their Niagara Falls plant, for instance, were using phosphate rock in the 1890s and 1900s from Connetable, Tennessee and Florida; by 1950 they were using phosphate rock mainly from Tennessee and North Africa. In the early 1990s Albright and Wilson's purified wet phosphoric acid business was being adversely affected by phosphate rock sales by China and the entry of their long-standing Moroccan phosphate suppliers into the purified wet phosphoric acid business.
In 2007, at the current rate of consumption, the supply of phosphorus was estimated to run out in 345 years. However, scientists are now claiming that a "Peak Phosphorus" will occur in 30 years and that "At current rates, reserves will be depleted in the next 50 to 100 years. The stability of the +5 oxidation state is illlustrated by the wide range of phosphate materials available in the earth.
3. Applications
Match striking surface made of a mixture of red phosphorus, glue and ground glass. The glass powder is used to increase the friction.
Widely used compounds
Use
Ca(H2PO4)2·H2O Baking powder and fertilizers
CaHPO4·2H2O Animal food additive, toothpowder
H3PO4 Manufacture of phosphate fertilizers
PCl3 Manufacture of POCl3 and pesticides
POCl3 Manufacturing plasticizer
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P4S10Manufacturing of additives and pesticides
Na5P3O10 Detergents
Phosphorus, being an essential plant nutrient, finds its major use as a constituent of fertilizers for agriculture and farm production in the form of concentrated phosphoric acids, which can consist of 70% to 75% P2O5. Global demand for fertilizers led to large increase in phosphate (PO4
3–) production in the second half of the 20th century. Due to the essential nature of phosphorus to living organisms, the low solubility of natural phosphorus-containing compounds, and the slow natural cycle of phosphorus, the agricultural industry is heavily reliant on fertilizers that contain phosphate, mostly in the form of superphosphate of lime. Superphosphate of lime is a mixture of two phosphate salts, calcium dihydrogen phosphate Ca(H2PO4)2 and calcium sulfate dihydrate CaSO4·2H2O produced by the reaction of sulfuric acid and water with calcium phosphate.
Phosphorus is widely used to make organophosphorus
compounds, through the intermediates phosphorus chlorides
and two phosphorus sulfides: phosphorus pentasulfide, and
phosphorus sesquisulfide.[13] Organophosphorus compounds
have many applications, including in plasticizers, flame
retardants, pesticides, extraction agents, and water treatment.
Phosphorus is also an important component in steel production,
in the making of phosphor bronze, and in many other related
products. Phosphorus is added to metallic copper during its
smelting process to react with oxygen present as an impurity in
copper and to produce oxygen-free copper or phosphorus-
containing copper (CuOFP) alloys with a higher thermal and
electrical conductivity than normal copper.
Phosphates are utilized in the making of special glasses that are
used for sodium lamps.
Bone-ash, calcium phosphate, is used in the production of fine
china.
Sodium tripolyphosphate made from phosphoric acid is used in
laundry detergents in some countries, but banned for this use in
others.
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Phosphoric acid made from elemental phosphorus is used in
food applications such as some soda beverages. The acid is also
a starting point to make food grade phosphates. These include
mono-calcium phosphate that is employed in baking powder and
sodium tripolyphosphate and other sodium phosphates. Among
other uses these are used to improve the characteristics of
processed meat and cheese. Others are used in toothpaste.
Trisodium phosphate is used in cleaning agents to soften water
and for preventing pipe/boiler tube corrosion.
Phosphorus sesquisulfide is used in heads of strike-anywhere
matches.
In trace amounts, phosphorus is used as a dopant for n-type
semiconductors.
32P and 33P are used as radioactive tracers in biochemical
laboratories (see Isotopes).
Phosphate is a strong complexing agent for the hexavalent
uranyl (UO22+) species and this is the reason why apatite and
other natural phosphates can often be very rich in uranium.
Tributylphosphate is an organophosphate soluble in kerosene
and used to extract uranium in the Purex process applied in the
reprocessing of spent nuclear fuel.
2.1.3. Arsen
Arsenic is the chemical element that has the symbol As, atomic number 33 and atomic mass 74.92. Arsenic was first documented by Albertus Magnus in 1250. Arsenic is a notoriously poisonous metalloid with many allotropic forms, including a yellow (molecular non-metallic) and several black and grey forms (metalloids). Three metalloidal forms of arsenic, each with a different crystal structure, are found free in nature (the minerals arsenic sensu stricto and the much rarer arsenolamprite and pararsenolamprite). However, it is more commonly found as arsenide and in arsenate compounds, several hundred of which are known. Arsenic and its compounds are used as pesticides, herbicides, insecticides and in various alloys.
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1. History
Arsenic sulfides (orpiment, realgar) and oxides have been known and used since ancient times. Zosimos (circa 300 AD) describes roasting sandarach (realgar) to obtain cloud of arsenic (arsenious oxide) which he then reduces to metallic arsenic. As the symptoms of arsenic poisoning were somewhat ill-defined, it was frequently used for murder until the advent of the Marsh test, a sensitive chemical test for its presence. (Another less sensitive but more general test is the Reinsch test.) Owing to its use by the ruling class to murder one another and its potency and discreetness, arsenic has been called the Poison of Kings and the King of Poisons.
During the Bronze Age, arsenic was often included in bronze, which made the alloy harder (so-called "arsenical bronze"). Albertus Magnus (Albert the Great, 1193–1280) is believed to have been the first to isolate the element in 1250 by heating soap together with arsenic trisulfide. In 1649, Johann Schröder published two ways of preparing arsenic.
Alchemical symbol for arsenic
Cadet's fuming liquid (impure cacodyl), the first organometallic compound, was synthesized in 1760 by Louis Claude Cadet de Gassicourt by the reaction of potassium acetate with arsenic trioxide.
2. Properties
a. Isotopes :
Naturally occurring arsenic is composed of one stable isotope, 75As. As of 2003, at least 33 radioisotopes have also been synthesized, ranging in atomic mass from 60 to 92. The most stable of these is 73As with a half-life of 80.3 days. Isotopes that are lighter than the stable 75As tend to decay by β + decay , and those that are heavier tend to decay by β - decay , with some exceptions.
At least 10 nuclear isomers have been described, ranging in atomic mass from 66 to 84. The most stable of arsenic's isomers is 68mAs with a half-life of 111 seconds.
Allotropes
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Structure of yellow arsenic As4 and white phosphorus P4
Like phosphorus, arsenic is an excellent example of an element that exhibits allotropy, as its various allotropes have strikingly different properties. The three most common allotropes are metallic grey, yellow and black arsenic. The most common allotrope of arsenic is grey arsenic. It has a similar structure to black phosphorus (β-metallic phosphorus) and has a layered crystal structure somewhat resembling that of graphite. It consists of many six-membered rings which are interlinked. Each atom is bound to three other atoms in the layer and is coordinated by each 3 arsenic atoms in the upper and lower layer. This relatively close packing leads to a high density of 5.73 g/cm3.
Yellow arsenic (As4) is soft and waxy, somewhat similar to P4. Both have four atoms arranged in a tetrahedral structure in which each atom is bound to each of the other three atoms by a single bond, resulting in very high ring strain and instability. This form of arsenic is the least stable, most reactive, most volatile, least dense, and most toxic of all the allotropes. Yellow arsenic is produced by rapid cooling of arsenic vapour with liquid nitrogen. It is rapidly transformed into the grey arsenic by light. The yellow form has a density of 1.97 g/cm3.
b. Chemical properties
The most common oxidation states for arsenic are −3 (arsenides: usually alloy-like intermetallic compounds), +3 (arsenates(III) or arsenites, and most organoarsenic compounds), and +5 (arsenates: the most stable inorganic arsenic oxycompounds). Arsenic also bonds readily to itself, forming square As3−4 ions in the arsenide skutterudite. In the +3 oxidation state, the stereochemistry of arsenic is affected by the presence of a lone pair of electrons.
Arsenic is very similar chemically to its predecessor in the Periodic Table, phosphorus. Like phosphorus, it forms colourless, odourless, crystalline oxides As2O3 and As2O5 which are hygroscopic and readily soluble in water to form acidic solutions. Arsenic(V) acid is a weak acid. Like phosphorus, arsenic forms an unstable, gaseous hydride: arsine (AsH3). The similarity is so great that arsenic will partly substitute for phosphorus in biochemical reactions and is thus poisonous. However, in subtoxic doses, soluble arsenic compounds act as stimulants, and were once popular in small doses as medicine by people in the mid 18th century.
When heated in air, arsenic oxidizes to arsenic trioxide; the fumes from this reaction have an odour resembling garlic. This odour can be detected on striking arsenide minerals such as arsenopyrite with a hammer. Arsenic (and some arsenic compounds) sublimes upon heating at atmospheric pressure, converting directly to a gaseous form without an intervening liquid state. The liquid state appears at 20 atmospheres and above, which explains why the melting point is higher than the boiling point.
3. Occurrence
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A large sample of native arsenic.
Arsenopyrite, also unofficially called mispickel, (FeAsS) is the most common arsenic-bearing mineral. In the lithosphere, the minerals of the formula M(II)AsS, with M(II) being mostly Fe, Ni and Co, are the dominant arsenic minerals.
Orpiment and realgar were formerly used as painting pigments, though they have fallen out of use owing to their toxicity and reactivity. Although arsenic is sometimes found native in nature, its main economic source is the mineral arsenopyrite mentioned above; it is also found in arsenides of metals such as silver, cobalt (cobaltite: CoAsS and skutterudite: CoAs3) and nickel, as sulfides, and when oxidised as arsenate minerals such as mimetite, Pb5(AsO4)3Cl and erythrite, Co3(AsO4)2·8H2O, and more rarely arsenites ('arsenite' = arsenate(III), AsO3
3− as opposed to arsenate (V), AsO43−).
In addition to the inorganic forms mentioned above, arsenic also occurs in various organic forms in the environment.Other naturally occurring pathways of exposure include volcanic ash, weathering of the arsenic-containing mineral and ores as well as groundwater. It is also found in food, water, soil and air.
4. Applications
a. Wood preservation :
The toxicity of arsenic to insects, bacteria, and fungi led to its use as a wood preservative. In the 1950s a process of treating wood with chromated copper arsenate (also known as CCA or Tanalith) was invented, and for decades this treatment was the most extensive industrial use of arsenic. Due to an increased understanding of arsenic's high level of toxicity, most countries banned the use of CCA in consumer products. The European Union and United States led this ban, beginning in 2004.
As of 2002, US-based industries consumed 19,600 metric tons of arsenic. 90% of this was used for treatment of wood with CCA. In 2007, 50% of the 5,280 metric tons of consumption was still used for this purpose. In the United States, the use of arsenic in consumer products was discontinued for residential and general consumer construction on December 31, 2003 and alternative chemicals are now used, such as Alkaline Copper Quaternary, borates, copper azole, cyproconazole, and propiconazole.
b. Other uses of arsen :
Various agricultural insecticides, termination and poisons. For
example Lead hydrogen arsenate was used well into the 20th
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century as an insecticide on fruit trees. Its use sometimes
resulted in brain damage to those working the sprayers. In the
last half century, monosodium methyl arsenate (MSMA) and
disodium methyl arsenate (DSMA), a less toxic organic form of
arsenic, has replaced lead arsenate's role in agriculture.
Used in animal feed, particularly in the US as a method of
disease prevention and growth stimulation. One example is
roxarsone which was used by 69.8 and 73.9% of the broiler
starter and growers between 1995 to 2000.
Gallium arsenide is an important semiconductor material, used
in integrated circuits. Circuits made using the compound are
much faster (but also much more expensive) than those made in
silicon. Unlike silicon it is direct bandgap, and so can be used in
laser diodes and LEDs to directly convert electricity into light.
Also used in bronzing and pyrotechnics.
Up to 2% of arsenic is used in lead alloys for lead shots and
bullets.
Arsenic is added in small quantities to brass to make it
dezincification resistant. This grade of brass is used to make
plumbing fittings.
Arsenic is also used for taxonomic sample preservation.
Until recently Arsenic was used in optical glass. Modern glass
manufacturers, under pressure from environmentalists, have
removed it, along with Lead.
Trimethylarsine Arsenobetaine
Inorganic arsenic and its compounds, upon entering the food chain, are progressively metabolised to less toxic forms of arsenic
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through a process of methylation. For example, the mold Scopulariopsis brevicaulis produce significant amounts of trimethylarsine if inorganic arsenic is present. The organic compound arsenobetaine is found in some marine foods such as fish and algae, and also in mushrooms in larger concentrations. The average person's intake is about 10–50 µg/day. Values about 1000 µg are not unusual following consumption of fish or mushrooms. But there is little danger in eating fish because this arsenic compound is nearly non-toxic. Some species of bacteria obtain their energy by oxidizing various fuels while reducing arsenate to arsenite. The enzymes involved are known as arsenate reductases (Arr).
5. Occupational exposures
Industries that use inorganic arsenic and its compounds include wood preservation, glass production, nonferrous metal alloys, and electronic semiconductor manufacturing. Inorganic arsenic is also found in coke oven emissions associated with the smelter industry. Occupational exposure and poisoning may occur in persons working in these industries
2.1.4.Antimony
Antimony (pronounced Latin: stibium) is a chemical element with the symbol Sb and an atomic number of 51. It has two stable isotopes, one with seventy neutrons, and the other with seventy-two. A silvery lustrous grey metalloid, it is found mainly as antimony sulfide, commonly known as stibnite. Elemental antimony has applications in electronics and as an alloy with other metals it is used for small arms ammunition.
1. History
One of the alchemical symbols for antimony
Antimony's sulfide compound, antimony(III) sulfide, Sb2S3 was recognized in antiquity, at least as early as 3000 BC. An artifact made of antimony dating to about 3000 BC was found at Tello, Chaldea (part of present-day Iraq), and a copper object plated with antimony dating between 2500 BC and 2200 BC has been found in Egypt. There is some uncertainty as to the description of the artifact from Tello. Although it is sometimes reported to be a vase, a recent detailed discussion reports it to be rather a fragment of indeterminate purpose. The first
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European description of a procedure for isolating antimony is in the book De la pirotechnia of 1540 by Vannoccio Biringuccio, written in Italian. This book precedes the more famous 1556 book in Latin by Agricola, De re metallica, even though Agricola has been often incorrectly credited with the discovery of metallic antimony. A text describing the preparation of metallic antimony that was published in Germany in 1604 purported to date from the early fifteenth century, and if authentic it would predate Biringuccio. The book, written in Latin, was called "Currus Triumphalis Antimonyi" (The Triumphal Chariot of Antimony), and its putative author was a certain Benedictine monk, writing under the name Basilius Valentinus. Already in 1710 Wilhelm Gottlob Freiherr von Leibniz, after careful inquiry, concluded that the work was spurious, that there was no monk named Basilius Valentinus, and the book's author was its ostensible editor, Johann Thölde (ca. 1565-ca. 1624). There is now agreement among professional historians that the Currus Triumphalis.. was written after the middle of the sixteenth century and that Thölde was likely its author. An English translation of the "Currus Triumphalis" appeared in English in 1660, under the title The Triumphant Chariot of Antimony. The work remains of great interest, chiefly because it documents how followers of the renegade German physician, Philippus Theophrastus Paracelsus von Hohenheim (of whom Thölde was one), came to associate the practice of alchemy with the preparation of chemical medicines.
According to the traditional history of Middle Eastern alchemy, pure antimony was well known to Jābir ibn Hayyān, sometimes called "the Father of Chemistry", in the 8th century. Here there is still an open controversy: Marcellin Berthelot, who translated a number of Jābir's books, stated that antimony is never mentioned in them, but other authors claim that Berthelot translated only some of the less important books, while the more interesting ones (some of which might describe antimony) are not yet translated, and their content is completely unknown.
The first natural occurrence of pure antimony ('native antimony') in the Earth's crust was described by the Swedish scientist and local mine district engineer Anton von Swab in 1783. The type-sample was collected from the Sala Silvermine in the Bergslagen mining district of Sala, Västmanland, Sweden.
2. Properties
a. Physical properties :
A vial containing a black allotrope of antimony Native massive antimony with oxidation products
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There are four known allotropes of antimony: a stable metallic form, and three meta-stable forms which are explosive, black and yellow. Each has its own distinct physical properties, the most common of which is metallic antimony, a brittle, silver-white shiny metal. When molten antimony is slowly cooled to metallic antimony, it forms with an hexagonal crystal structure, isomorphic with that of the grey form of arsenic.
The explosive form of antimony is formed from the electrolysis of antimony(III) trichloride, under specific temperatures and concentration. In a bath of hydrochloric with an antimony anode and platinum foil cathode, explosive antimony is deposited on the latter. When scratched with a sharp implement, an exothermic reaction occurs and white fumes given off as metallic antimony is formed; alternatively, when rubbed with a pestle in a mortar, an strong detonation occurs. Black antimony is formed when gaseous metallic antimony is rapidly cooled. It oxidies in air and is sometimes spontaneously combustible. At 100 °C, it gradually transforms into the stable form. Finally, the yellow allotrope of antimony is the most unstable. While it cannot be produced as the black allotrope by rapid cooling, it can only be formed by introducing oxygen into antimony hydride at -90 °C. Above this temperature and in ordinary light, it transforms into the stabler black allotrope.
b. Chemistry
Antimony trioxide (Sb4O6) is formed when antimony is burnt in an excess of air. In the gas phase, this compound exists as Sb4O6, a species that is retained when cooled to its solid, cubic form. However, in the rhombic form, the molecules polymerise to form chains of [Sb2O3]x. Antimony pentoxide, (Sb4O10) can only be formed by oxidation by concentrated nitric acid. Antimony also forms a mixed-valence oxide, antimony tetroxide (Sb2O4), where it is found in both the +3 and +5 oxidation states. Unlike phosphorus and arsenic, these various oxides are amphoteric and do not form well-defined oxoacids and react with acids to form antimony salts. Antimony trioxide dissolves in concentrated acid to form antimony oxo- (antimonyl) compounds such as SbOCl and (SbO)2SO4. The hypothetical antimonous acid Sb(OH)3 only exists as its salts,[19]:763 such as sodium antimonyte ([Na3SbO3]4), formed by fusing sodium oxide and Sb4O6. Transition metal antimonytes are best described as mixed metal oxides. Antimonyc acid exists only as the hydrate HSb(OH)6, forming salts containing the antimonate anion Sb(OH)−6. Dehydrating metal salts containing this anion yields mixed oxides.
Many antimony ores are sulfides, including stibnite (Sb2S3), pyrargyrite (Ag3SbS3), zinkenite, jamesonite, and boulangerite. Antimony pentasulfide is known, but is non-stoichiometric and contains only antimony in the +3 oxidation state. Several complex anions of antimony and sulfur are known, such as [Sb6S10]2− and [Sb8S13]2−.
Antimony forms two series of halides: SbX3 and SbX5, where X is one of the halogens. The trihalides SbF3, SbCl3, SbBr3, and SbI3 are all
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molecular compounds having trigonal pyramidal molecular geometry. The trifluoride SbF3 is prepared by the reaction of Sb2O3 with HF.
Sb2O3 + HF → 2 SbF3 + 3 H2O
It is a strong Lewis acid that readily accepts fluoride ions to form the complex anions SbF−4 and SbF2−5. Molten SbF3 is a weak electrical conductor.
The trichloride SbCl3 is prepared by dissolving Sb2S3 in hydrochloric acid:
Sb2S3 + HCl → 2 SbCl3 + 3 H2S
The pentahalides SbF5 and SbCl5 have trigonal bipyramidal molecular geometry in the gas phase, but in the liquid phase, SbF5 is polymeric, whereas SbCl5 is monomeric. SbF5 is a powerful Lewis acid used to make the superacid fluoroantimonyc acid (HSbF6), and is an important solvent used in the study of noble gas compounds.
Antimony forms antimonydes with metals, such as indium antimonyde (InSb), and silver antimonyde (Ag3Sb). Treating antimonydes with acid produces the unstable toxic gas stibine, SbH3.
Sb3− + 3 H+ → SbH3
Stibine may also be produced by reacting Sb3+ salts with sources of the hydride ion H−. Antimony does not react with hydrogen directly to form stibine.
3. Occurrence and Production
The abundance of antimony in the Earth's crust is estimated at 0.2 to 0.5 parts per million, comparable to thallium at 0.5 parts per million and silver at 0.07 ppm. Even though this element is not abundant, it is found in over 100 mineral species. Antimony is sometimes found native, but more frequently it is found in the sulfide stibnite (Sb2S3) which is the predominant ore mineral. Commercial forms of antimony are generally ingots, broken pieces, granules, and cast cake. Other forms are powder, shot, and single crystals.
In 2005, China was the top producer of antimony with about 84% world share followed at a distance by South Africa, Bolivia and Tajikistan, reports the British Geological Survey. The mine with the largest deposits in China is Xikuangshan mine in Hunan Province with a estimated deposit of 2.1 million metric tons. Antimony is isolated from its ore by a reduction with scrap iron:
Sb2S3 + 3Fe → 2Sb + 3FeSIsolating antimony from its oxide, is performed by a charcoal reduction:
2Sb2O3 + 3C → 4Sb + 3CO2
4. Applications
a. Elemental antimony and alloys
Elemental antimony is increasingly being used in the
semiconductor industry as a dopant for ultra-high conductivity n-
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type silicon wafers in the production of diodes, infrared detectors,
and Hall-effect devices. It is also used as an alloy, to increase lead's
hardness and mechanical strength, as in lead-acid batteries, which is
the most common use of antimony. It is used in antifriction alloys, such
as Babbit metal. It is used as an alloy in small arms ammunition,
buckshot, tracer ammunition, cable sheathing, type metal (e.g.
for linotype printing machines), solder – some "lead-free" solders
contain 5% Sb in pewter, and in hardening alloys with low tin content
in the manufacturing of organ pipes.
In the 1950s, tiny beads of a lead-antimony alloy were used to
dope the emitters and collectors of NPN alloy junction transistors
with antimony. A coin made of antimony was issued in the Keichow
Province of China in 1931. The coins were not popular, being too soft
and they wore quickly when in circulation. After the first issue no
others were produced. Elemental antimony as an antimony pill was
once used as a medicine. It could be reused by others after ingestion.
Treatments principally containing are known as antimonyals
and are used as emetics.Antimony compounds are used as
antiprotozoan drugs. Antimony potassium tartrate, or tartar
emetic, has been used in the past as an anti-schistosomal drug, later
replaced by praziquantel.
Antimony and its compounds are used in several veterinary preparations like anthiomaline or lithium antimony thiomalate, which is used as a skin conditioner in ruminants.
Antimony has a nourishing or conditioning effect on keratinized tissues, at least in animals. Antimony-based drugs, such as meglumine antimonyate, are also considered the drugs of choice for treatment of leishmaniasis in domestic animals. Unfortunately, as well as having low therapeutic indices, the drugs are poor at penetrating the bone marrow, where some of the Leishmania amastigotes reside, and so cure of the disease – especially the visceral form – is very difficult.
b. Other uses of antimony :
In the heads of some safety matches in nuclear reactors together with beryllium in startup neutron sources; in the form of antimony oxides, antimony sulfides, and antimony trichloride are used in the making of flame-proofing compounds, ceramic enamels, glass, paints, and pottery. Antimony trioxide is the most important of the antimony compounds and is primarily used in flame-retardant formulations. These flame-retardant applications include such markets
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as children's clothing, toys, aircraft and automobile seat covers. It is also used in the fiberglass composites industry as an additive to polyester resins for such items as light aircraft engine covers. The resin will burn while a flame is held to it but will extinguish itself as soon as the flame is removed.
2.1.5.Bismut
Bismuth is a chemical element that has the symbol Bi and atomic number 83. This trivalent poor metal chemically resembles arsenic and antimony. Bismuth is heavy and brittle; it has a silvery white color with a pink tinge owing to the surface oxide. Bismuth is the most naturally diamagnetic of all metals, and only mercury has a lower thermal conductivity. It is generally considered to be the last naturally occurring stable, non-radioactive element on the periodic table, although it is actually slightly radioactive. Its only non-synthetic isotope bismuth-209 decays via alpha decay into thallium-205, with an extremely long half-life of 1.9 × 1019 years.
Bismuth compounds are used in cosmetics, medicines, and in medical procedures. As the toxicity of lead has become more apparent in recent years, alloy uses for bismuth metal as a replacement for lead have become an increasing part of bismuth's commercial importance.
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Bismuth crystal with an iridescent oxide surface Bismuth crystals
Bismuth is a brittle metal with a white, silver-pink hue, often occurring in its native form with an iridescent oxide tarnish showing many colors from yellow to blue. The spiral stair stepped structure of a bismuth crystal is the result of a higher growth rate around the outside edges than on the inside edges. The variations in the thickness of the oxide layer that forms on the surface of the crystal causes different wavelengths of light to interfere upon reflection, thus displaying a rainbow of colors. When combusted with oxygen, bismuth burns with a blue flame and its oxide forms yellow fumes. Its toxicity is much lower than that of its neighbors in the periodic table such as lead, tin, tellurium, antimony, and polonium.
Although ununpentium is theoretically more diamagnetic, no other metal is verified to be more naturally diamagnetic than bismuth. (Superdiamagnetism is a different physical phenomenon). Of any metal, it has the second lowest thermal conductivity (after mercury) and the highest Hall coefficient. It has a high electrical resistance. When deposited in sufficiently thin layers on a substrate, bismuth is a semiconductor, rather than a poor metal.
Elemental bismuth is one of very few substances of which the liquid phase is denser than its solid phase (water being the best-known example). Bismuth expands 3.32% on solidification; therefore, it was long an important component of low-melting typesetting alloys, where it compensated for the contraction of the other alloying components.
Though virtually unseen in nature, high-purity bismuth can form distinctive hopper crystals. These colorful laboratory creations are typically sold to collectors. Bismuth is relatively nontoxic and has a low melting point just above 271°C, so crystals may be grown using a household stove, although the resulting crystals will tend to be lower quality than lab-grown crystals.
1. History
Bismuth (New Latin bisemutum from German Wismuth, perhaps from weiße Masse, "white mass") was confused in early times with tin and lead because of its resemblance to those elements. Bismuth has been known since ancient times, and so no one person is credited with its discovery. Agricola, in De Natura Fossilium states that bismuth is a distinct metal in a family of metals including tin and lead in 1546 based on observation of the metals and their physical properties. Claude François Geoffroy demonstrated in 1753 that this metal is distinct from lead and tin.
"Artificial bismuth" was commonly used in place of the actual metal. It was made by hammering tin into thin plates, and cementing them by a mixture of white tartar, saltpeter, and arsenic, stratified in a crucible over an open fire.
Bismuth was also known to the Incas and used (along with the usual copper and tin) in a special bronze alloy for knives.
2. Occurrence and production
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Bismite mineral
In the Earth's crust, bismuth is about twice as abundant as gold. It is not usually economical to mine it as a primary product. Rather, it is usually produced as a byproduct of the processing of other metal ores, especially lead, tungsten (China), tin, copper, and also silver (indirectly) or other metallic elements.
The most important ores of bismuth are bismuthinite and bismite. In 2005, China was the top producer of bismuth with at least 40% of the world share followed by Mexico and Peru, reports the British Geological Survey. Native bismuth is known from Australia, Bolivia, and China.
3. Recycling
While bismuth is most available today as a byproduct, its sustainability is more dependent on recycling. Bismuth is mostly a byproduct of lead smelting, along with silver, zinc, antimony, and other metals, and also of tungsten production, along with molybdenum and tin, and also of copper production. Recycling bismuth is difficult in many of its end uses, primarily because of scattering. Probably the easiest to recycle would be bismuth-containing fusible alloys in the form of larger objects, then larger soldered objects. Half of the world solder consumption is in electronics (i.e., circuit boards). As the soldered objects get smaller or contain little solder or little bismuth, the recovery gets progressively more difficult and less economic, although solder with a sizable silver content will be more worth recovering. Next in recycling feasibility would be sizeable catalysts with a fair bismuth content, perhaps as bismuth phosphomolybdate, and then bismuth used in galvanizing and as a free-machining metallurgical additive. Finally, the bismuth in the uses where it gets scattered the most, in stomach medicines (bismuth subsalicylate), paints bismuth vanadate on a dry surface, pearlescent cosmetics (bismuth oxychloride), and bismuth-containing bullets.
The most important sustainability fact about bismuth is its byproduct status, which can either improve sustainability (i.e., vanadium or manganese nodules) or, for bismuth from lead ore, constrain it; bismuth is constrained. The extent that the constraint on bismuth can be ameliorated or not is going to be tested by the future of the lead storage battery, since 90% of the world market for lead is in storage batteries for gasoline or diesel-powered motor vehicles.
The life-cycle assessment of bismuth will focus on solders, one of the major uses of bismuth, and the one with the most complete information. The average primary energy use for solders is around 200 MJ per kg, with the high-bismuth solder (58% Bi) only 20% of that value, and three low-bismuth solders (2% to 5% Bi) running very close
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to the average. The global warming potential averaged 10 to 14 kg carbon dioxide, with the high-bismuth solder about two-thirds of that and the low-bismuth solders about average. The acidification potential for the solders is around 0.9 to 1.1 kg sulfur dioxide equivalent, with the high-bismuth solder and one low-bismuth solder only one-tenth of the average and the other low-bismuth solders about average. There is very little life-cycle information on other bismuth alloys or compounds.
4. Chemistry properties
Bismuth forms trivalent and pentavalent compounds. The trivalent compounds are more common. Many of its chemical properties are similar to other elements in its group; namely, arsenic and antimony, although it is less toxic than those elements.
Bismuth is stable to both dry and moist air at ordinary temperatures. At elevated temperatures, the vapours of the metal combine rapidly with oxygen, forming the yellow trioxide, Bi2O3 On reaction with base, this oxide forms two series of oxyanions: BiO−2, which is polymeric and forms linear chains, and BiO3−3. The anion in Li3BiO3 is actually a cubic octameric anion, Bi8O24−24, whereas the anion in Na3BiO3 is tetrameric.
Bismuth sulfide, Bi2S3, occurs naturally in bismuth ores. It is also produced by the combination of molten bismuth and sulfur. Unlike earlier members of group 15 elements such as nitrogen, phosphorus, and arsenic, and similar to the previous group 15 element antimony, bismuth does not form a stable hydride analogous to ammonia and phosphine. Bismuth hydride, bismuthine (BiH3), is an endothermic compound that spontaneously decomposes at room temperature. It is stable only below −60°C.
The halides of bismuth in low oxidation states have been shown to have unusual structures. What was originally thought to be bismuth(I) chloride, BiCl, turns out to be a complex compound consisting of Bi5+9 cations and BiCl2−5 and Bi2Cl2−8 anions. The Bi5+9 cation has a distorted tricapped trigonal prismic molecular geometry, and is also found in Bi10Hf3Cl18, which is prepared by reducing a mixture of hafnium(IV) chloride and bismuth chloride with elemental bismuth, having the structure [Bi+][Bi5+9][HfCl2−6]3. Other polyatomic bismuth cations are also known, such as Bi2+8, found in Bi8(AlCl4)2. Bismuth also forms a low-valence bromide with the same structure as "BiCl". There is a true monoiodide, BiI, which contains chains of Bi4I4 units. BiI decomposes upon heating to the triiodide, BiI3, and elemental bismuth. A monobromide of the same structure also exists.
In oxidation state +3, bismuth forms trihalides with all of the halogens: BiF3, BiCl3, BiBr3, and BiI3. All of these, except BiF3, are hydrolysed by water to form the bismuthyl cation, BiO+, a commonly encountered bismuth oxycation.[14] Bismuth(III) chloride reacts with hydrogen chloride in ether solution to produce the acid HBiCl4.
Bismuth dissolves in nitric acid to form bismuth(III) nitrate, Bi(NO3)3. In the presence of excess water or the addition of a base, the
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Bi3+ ion reacts with the water to form BiO+, which precipitates as (BiO)NO3. The oxidation state +5 is less frequently encountered. One such compound is BiF5, a powerful oxidising and fluorinating agent. It is also a strong fluoride acceptor, reacting with xenon tetrafluoride to form the XeF+3 cation:
BiF5 + XeF4 → XeF + 3BiF−6
The dark red bismuth(V) oxide, Bi2O5, is unstable, liberating O2 gas upon heating. In aqueous solution, the Bi3+ ion exists in various states of hydration, depending on the pH:
pH range
Species
<3 Bi(H2O)3+6
0-4 Bi(H2O)5OH2+
1-5Bi(H2O)4(OH)2+
5-14Bi(H2O)3(OH)3
>11Bi(H2O)2(OH)4−
These mononuclear species are in equilibrium. Polynuclear species also exist, the most important of which is BiO+, which exists in hexameric form as the octahedral complex [Bi6O4(OH)4]6+ (or 6 [BiO+]·2 H2O).
5. Applications
Bismuth oxychloride is sometimes used in cosmetics. Bismuth subnitrate and bismuth subcarbonate are used in medicine.a) Health
Bismuth subsalicylate (the active ingredient in Pepto-Bismol and
(modern) Kaopectate) is used as an antidiarrheal and to treat
some other gastro-intestinal diseases (oligodynamic effect). The
means by which this appears to work is still not well-
documented. It is thought to be some combination of:
Killing some bacteria that cause diarrhea
Reducing inflammation/irritation of stomach and intestinal
lining
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Retarding the expulsion of fluids into the digestive system
by irritated tissues, by "coating" them.
The product Bibrocathol is an organic molecule containing
Bismuth and is used to treat eye infections.
Bismuth subgallate (the active ingredient in Devrom) is used as
an internal deodorant to treat malodor from flatulence (or gas)
and faeces.
Historically Bismuth compounds were used to treat Syphilis and
today Bismuth subsalicylate and Bismuth subcitrate are used to
treat the Peptic ulcer.
b) Other uses
Strong permanent magnets can be made from the alloy
Bismanol (BiMn).
Bismuth has a potential role in electronic circuits and in
manufacturing next-generation solar cells which would have a
greater efficiency. Bismuth allows for the creation of new diodes
that can reverse their direction of current flow.
Many bismuth alloys have low melting points and are widely
used for fire detection and suppression system safety devices.
Bismuth is used as an alloying agent in production of malleable
irons.
It is also used as a thermocouple material.
A carrier for U-235 or U-233 fuel in nuclear reactors.
Bismuth is also used in solders. The fact that bismuth and many
of its alloys expand slightly when they solidify makes them ideal
for this purpose.
Bismuth subnitrate is a component of glazes that produces an
iridescent luster finish.
Bismuth telluride (a semiconductor) is an excellent
thermoelectric material. Bi2Te3 diodes are used in mobile
refrigerators and CPU coolers. Also used as detectors in Infra red
spectrophotometers.
A replacement propellant for xenon in Hall effect thrusters
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Bismuth is included in BSCCO (Bismuth Strontium Calcium
Copper Oxide) which is a group of similar superconducting
compounds discovered in 1988 among which is the highest
temperature superconductor yet known with a transition
temperature of 110K.[23]
Bi-213 can be produced by bombarding radium with
bremsstrahlung photons from a linear particle accelerator. In
1997 an antibody conjugate with Bi-213, which has a 45 minute
half-life, and decays with the emission of an alpha-particle, was
used to treat patients with leukemia. This isotope has also been
tried in cancer treatment, e.g. in the Targeted Alpha Therapy
(TAT) program.[24]
The delta form of bismuth oxide when it exists at room
temperature is a solid electrolyte for oxygen. This form normally
only exists above and breaks down below a high temperature
threshold, but can be electrodeposited well below this
temperature in a highly alkaline solution.
RoHS initiative for reduction of lead has broadened bismuth's
use in electronics as a component of low-melting point solders,
as a replacement for traditional tin-lead solders.
As noted above, bismuth has been used in lead-free solders; its
low toxicity will be especially important for solders to be used in
food processing equipment and copper water pipes, although it
can also be used in other applications including those in the
automobile industry, in the EU for example.
A catalyst for making acrylic fibers
Ingredient in lubricating greases
Dense material for fishing sinkers
2.2. Elements of group VB
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VB group consists of four elements, namely Vanadium (V), niobium (Nb), Tantalum (Ta). Some properties of the elements of this group we can see in the following :
PropertiesVanadium
(V23)Niobium (Nb4i)
Tantalium (Ta73)
Dubnium (Dbios)
Configuration 2, 8, 11, 22, 8, 18,
12, 12, 8, 18, 32,
11, 22, 8, 18, 32,
32, 11, 2
Outermost electrons 3d3 4s2 4d4 5s1 5d3 6s2 5f14 6d3 7s2
Mass atom (g/mol) 50, 94 92, 91 130, 95 268
Period type 6,1 8,4 16,6 -
Melting point (0C) 1900 2468 2996 -
Boiling point (0C) 3450 3300 5425 -
Radius atom (0A) 1,34 1,46 1,49 -
Ionic radius (0A) 0,59 0,70 0,73 -
Inization potensial first
6,74 6,80 7,00 -
Electronegativity 1,6 1,6 1,5 -
Oxidation -1, 0, +1, +2, +3, +4, +5
-1,+2,+3,+4, +5
-1, +2, +3, +4, +5
+3, +4, +5
Steam Heat 106 - 180 -
Heat of melting 4,2 6,4 6,8 -
Capasity calor (250C)J(mol 0K)
24.89 24.60 25.36
Magnetic propertiesParamagn
etic- - -
Electrical properties (N0m)
(20 °C) 197
(0 °C) 152 (20 °C) 131 -
Conductivity thermal 30.7 53.7 57.5 -
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(300K) (W.m-1K-1)
Thermal Expansion 8.4 7.3 6.3 -
Speed of sound (On from wire) (200C)
4560 m/s 3480 m/s 3400 m/s -
Young’s Modulus 128 GPa 105 GPa 186 GPa -
Shear Modulus 47 GPa 38 GPa 69 GPa -
Hardness scale Mohs
6.7 6.0 6.5 -
Outermost elektron V ( 3d3 4S2 ), Nb ( 4d4 4S1 ), Ta ( rd3 4S2 ). Nomer oxsidation varied, stability of +5 oxsidation state increases from V-Nb-Ta. Thus V+5 easily reduced to V+2 is Nb+5 and Ta+5 remained stable, V+5 is a good oxidant. The unique nature of each elements diminished view of the reduced size of cations. Thus, the unique nature of V+4 > V+3 > V+2. Consequently VC14 covalen character. Oxide properties , V205 amphoter but more acidic, while Nb205 and Ta205 fever bases.
Unreactive at room temperature but on heating reacts to from VC15, VC14, VC13, dan VI3. Nb and Ta are formed only halide type MX5. All halides are covalen and volatile. With H2 from non-stoichiometric compuonds, VH0,7 ; NbH0,86 and TaH0,76. Tendency from a complex : V > Nb > Ta. Radius (ionic and atomic) Nb with Ta is almost the same as a result lanthanida contraction, so that bolt are almost the same properties.
Compounds these metals with an oxidation number lower winnowing colored because of the d orbitals that contain partially.
2.2.1. Vanadium
1. History and discovery :
In 1831, Swedish chemist, Niel Grabiol Sefstrom discover new elements in the iron ore in Sweden. The elements was named Vanadium as a means goddess Vanadis gorgeous. Year 1865 Roscor and Thorpe found this elements to be with layers of copper and lawer
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standstone of Cheshire. Vanadium compounds are abundant in scattered earth’s crust. Some prominent vanadium minerals is :
vanadinite : 3 Pb3(VO4)2 . PbCl2
carnotite : K2O . 2UO3 . V2O53H2O
patronite : V2S5 . 3CuS2
Vanadium also occurs in the clay, rocks, coal and crude oil with a small degree.
How to get the vanadium them is by extraction from several compounds, namey :
a) From vanadinite, extraction from ore involves several stages:
Separation of PbCl2
Ore is reacted with concentrated HCl, PbCl2 will settle, dioxovandium chlotida (VO2Cl) remained in solution.
Making V2O5
PbCl2 after inseparable, solution plus NH4C1 and saturated with NH3, forming NH4VO3 which when formed V205.
Reduction of V205.
V205 reduced by Ca in the 900 - 950 ° C to obtain pure vanadium.
b) From carnotite.
The making of sodium orthovanadate.
Carnotite melted with Na2C03, the liquid obtain extracted with water to precipitate Fe(OH)3, evaporated and cooled the importance of the Na3V04.
Making V205.
Solution containing Na3V04 given NH4C1 and saturated NH3, forming NH4V03 (amonium metavanadate), heated to obtain V205.
Reduction of V205.
Rich Mardenand way of vanadium metal was obtained pure.
2. Manufacture of metals :
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This metal is very hard to obtain in a pure state because the melting and high reactivity toward O2, N2 and C at high temperature.
Vanadium ± 99 % can be obtained by V205 with Al (thermit
process).
Pure Vanadium was obtained by reducing VC13 with Na or
with H2 at temperature 900 ° C. VC13 obtained from V205 with
S2C12 at 300 °C.
VC14 reduction with Mg can be obtained 99,3 % vanadium.
3. Aliase vanadium :
Commercial products are mainly as aliase vanadium,
Ferro vanadium and Cupro vanadium
Both are made by reducing vanadium mixed oxide with Fe or Cu with carbon preformance in the electric furnace.
Nikelo vanadium, made by healting a mixture of V205 + NiO.
Obalto vanadium, created by mixing sediment (from the
reactive Na-vanadate solutions with cobalto sulphate) with
Na2C03 electric furnace.
4. Usage :
Addition of 0,1 to 0,3 % V steel will increase the power range.
Vanadium is important for the tools of high speed steel.
V205 used as a catalyst in oxidation naphtalen and also in
making H2S04 contact process.
5. Properties :
Healted H2 (no other gases) at 1100°C to vanadium hydride
is stable.
These metal reactive in cold conditions, when heated formed
V20 (brown), hested hold formed V203 (black), V204 (blue),
end the V205 (orange). These metals burn with a bright flame
with oxygen.
When heated with Cl2 fromed dry VC14.
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This metal does not reactive with bromine water, HCl/winter,
releasing H2 with HF and forming a green solution.
6. Substances :
Vanadium form compounds with oxidation numbr +5, +4, +3 and +2. Compounds with lower oxidation number is reducing agent,is unique and colorful.
1. Compounds V+5 (colorless) is reducted with a reducing agent
according to the following changes :
a. Vanadium pentoksida, V2O5
Made from:
Oxidation/ metal or oxide , toasting with low oxidation states.
V2O5 as the final result.
Hyidrolysis VOCl3.
Heating amonium vanadate.
Usage :
As a catalyst in the oxidation of SO2 → SO3, in sulfuric acid.
V2O5
2SO2 + O2 ↔ 2SO3
Catalyst in a alcohol oxidation and hydrogenation of olefin.
b. Vanadium pentaflourida, VF5.
This compounds is expressed as sublimat pure white. Be made with heating VF4 in a nitrogen environment, at a temperature 350°C – 650°C. This compounds is very solube in water or organic solvents.
c. Vanadium oxitrikhlorida, VOCl3.
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This compounds is made by passing Cl2 dried at VO3to be heated. This compounds is yellow with a translucent boiling point 127 ° C.
d. Vanadium pentasulfida, V2S5.
This compounds is made by heating mixture of vanadium trisulfida, with sulfur without air at 400 ° C. This compounds form black powder.
2. Compound V+4.
Compounds with a +4 oxidation state is stable, easy to manufacture.
a. Vanadium titroksida, V2O4 atau VO2.
Created by heating a mixture of vanadium trioksida and vanadium pentoksida without air with a molar amount same. These compounds form a dark blue cystal, easily soluble acid or alkaline.
b. Vanadium titraflourida, VF4.
Created from the reaction of HF anhydride with VCl4. Start temperature –28°C and rose slowly to 0°C. Flouride is a brownish yellow powder, soluble in water forming a blue solution.
3. Compounds Vanadil
This compound contains a cation vanadil (VO+2) where the number oxidation +4, is unique, colored blue. Vanadil chloride made from the hydrolysis VCl4
VCl4 + H2O → VOCl2 + 2HCl
Or from the hydrolysis V2O5 with HCl
V2O5 + HCl → 2VOCl2 +3H2O + Cl2
VOCl2 compounds are strong reducing agents that are used commercial in coloration. Only the E° of VO+2/ VO3 is –1 volt.
4. Compound V+3.
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a. Vanadium trioxside, V2O3.
Created by reducing V2O5 with hydrogen. V2O3 is alkaline, soluble in acid gives hezaquo ions, V(H2O)6
3+.
b. oxihalida halide and Vanadium.
Vanadium triflourida, VF3.3H2O created when the V2O3 dissolved HF. Trihalida the other is the VCl3 and VBr3, moderate VI3 not known. Vanadium oxihalida is known VOCl and VOBr. Both are insoluble in water but soluble in acid.
5. Compound V+2.
Compound V+2 colored and paramagnetic ion V+2 is a strong reducing agent. V+2 dilute solution (violet) to reduce water liberate H2.
V+2 + H+ → V+3 + ½ H2
(violet) (green)
6. Compound V+1, V-1 and V°.
Oxidation is not common, stabilized by the ligand acid Π. Oxidation numer +1 was found in compound V(CO)6
-1.
2.2.2.Niobium and Tantalum
Although these two elements are metals in some respects, chemical properties such as non logam Although these two elements has no cation real, but formed several anions. Halides and very oxihalida hydrolysed volatile and easily.
Niobium Tantalum
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1. History of Niobium and Tantalum
Niobium was discovered by British chemist from the Charles Hatchett in the year 1801. Hatchett found in samples of niobium minerals columbite and called the new element columbium. Columbium discovered by Hatchett in a mixture with Tantalum. Tantalum itself was discovered by a chemist Anders Ekeberg Sweden.
Then confusion arises between the two element are both are the same element or not. Then in 1809, English chemist William Hyde Wollaston comparing shapes oxidation that occurred columbium – columbite, with a density 5918 g/ml, and tantalum – tantalite with a density 7935 g/ml, and concluded that both elements are different because the course has different densities, so the name became niobium and columbium be Tantalum fixed Tantalum.
2. Properties :
Both metals are very difficult to separate. Niobium metal is thin, soft, grayish, shiny, can be bent, high melting point (Nb= 2468 ° C). Tantalum metal is dark, dense, can be bent, the haerder than Niobium, electrical conductivity and high heat, high melting point (Ta = 2996° C), very resistant to acid. Both can be dissolved with HNO3, HF and dissolve very slowly in the alkaline liquid.
3. Compounds :
a) Compound Nb+5 and Ta+5
Nb2O5 and Ta2O5
Created by dihydroksioksida hydrate (often called acid niobat or tantalat), or by roasting a particular compound with excess oxygen. Both these compound are in powder from dense, relatively inert chemically, almost did not react with acid except for concentrated HF. These compound can be dissolved with melted with alkaline hydrogen sulphate, alkali carbonate or alkali hydroxide.
NbX5 and TaX5 (X = halide).
Compounds NbF5 and TaF5 prepared by reaction direct flourinasi metal or pentachlorida. Both are solid white. It’s easy yawn. Melting point of Nb = 80 ° C, Ta = 95 ° C. boiling point Nb = 235 ° C, Ta = 229 ° C, forming a colorless liquid and vapor. Compound other
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halide yellow to brown, made with the reaction direct metal with excess halogen. Halide is dotted halides liquid and boiling point between 200 - 300 ° C, soluble in organic solvents such us ether, CC14, and so forth.
b) Compound Nb and Ta with low oxidation state.
Nb02Oxide and TaOx (x = 2 s.d 2,5)
Tetrahalida.
All halides known except TaF4. Compound NbF4 not very volatile, paramagnetic. Tetrakhlorida and colored tetrakronida dark brown ao black. Nbl4 can be obtained easily by heating NbI5 up to 300° C. these compounds diamagnetism.
4. Applications
Niobium
• As a material for nuclear powder plant construction.
• As a mixture of rust resistant metal (example Niobium foil),
caused by the presence of Niobium carbide and compound
Niobium Nitrit, with the concentration of Niobium in the
compound approximately 0.1%.
• As a superconducting magnet (3 tesla clinical Magnetic
resonance imaging scanner), and superconducting radio
frequency.
• The manufacture of coin currency (example Austria 2003, Latvia
2004).
• In medical equipment, Pace maker.
• In the manufacture of jewelry.
Tantalum
• Used in the manufacture of children in a loboratory scale.
• Used in making electronic devices.
• In making the camera lens.
• To produce variations of the alloy that has a point high boiling
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and the forces of good.
• Preparation of equipment made of metal carbide.
• Used in the manufacture of jet engine components.
2.2.3.Dubnium
Dubnium is an element of group Vb transition metals are made though nuclesr fusion reactions. This eleemnt was discovered by Albert Ghiorso in 1970. Because of very large nuclei dubnium then dubnium constituents stable and not readily disintegrate.
Dubnium elements can br created by firing element amerisium with atoms of neon, adn produces isotopes dubnium isotopes, and quickly decays by emitting in the from of electromagnetic radition. Reaction as follows :
Compound s that can be formed for example Db205 (Dubnium pentoxide), DbX5 (Dubnium Halide), halide complexes Db04
3" , DbF6", DbF8
3. Other information about the elements Dubnium not clesrly known.
CHAPTER III
SUMMARY
1. Groups VA consist of Nitrogen, Phospor, Arsenic, Antimony , and
Bismut. Groups VB consist of Vanadium, Niobium, Tantalum, and
Dubnium.
2. Nitrogen has use for freeze.
3. Match striking surface made of a mixture of red phosphorus, glue
and ground glass. The glass powder is used to increase the friction.
4. The toxicity of arsenic to insects, bacteria, and fungi led to its use
as a wood preservative.
5. Elemental antimony is increasingly being used in the
semiconductor industry.
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6. Bismuth oxychloride is sometimes used in cosmetics. Bismuth
subnitrate and bismuth subcarbonate are used in medicine.
7. Outermost elektron V ( 3d3 4S2 ), Nb ( 4d4 4S1 ), Ta ( rd3 4S2 ).
Nomer oxsidation varied, stability of +5 oxsidation state increases
from V-Nb-Ta.
8. Tendency from a complex : V > Nb > Ta.
9. Compounds these metals with an oxidation number lower
winnowing colored because of the d orbitals that contain partially.
10.Vanadium is important for the tools of high speed steel, V205 used as
a catalyst in oxidation naphtalen and also in making H2S04 contact
process.
11. Niobium as a material for nuclear powder plant construction and as
a mixture of rust resistant metal.
12.Tantalum used in the manufacture of children in a loboratory scale
and used in making electronic devices.
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REFERENCES
Chang, Raymond. 2005. Kimia Dasar Jilid I. Jakarta: Erlangga
Cotton dan Wilkinson. 1989. Dasar Anorganik Kimia. Jakarta : UI-Press
Gianto. 2009. “Sistem Periodik Unsur dan Struktur Atom”. http://arsipegianto.tripod.com/perkspu.pdf, tanggal 20 september 2010, pukul 12:09:10
http://alvina.blog.uns.ac.id/2008/12/30/unsur-golongan-vb/, date September 18th 2010, time 10:17:26 AM
http://indice.blog.uns.ac.id/files/2010/05/unsur-gol-vb.pdf, date September 7th 2010, time 03:48:11 PM
http://www.lenntech.com/periodic/elements/n.htm#ixzz1bXce3Hgh, date September 13th 2010, pukul 07:35:57 PM
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