Post on 28-Dec-2015
ELECTRONS IN THE ATOM
UNIT 4
OBJECTIVES
1. Explain how atomic emission spectra can be used to identify elements
2. Describe Bohr’s model of the atom.3. Describe the Quantum Mechanical
model of the atom4. Write elements’ electron
configurations.
HOW DO WE KNOW WHAT THE STARS ARE MADE OF?
ATOMIC EMISSION SPECTRA• When an element is heated, its atoms absorb
energy and become excited• To become stable again, these excited and
unstable atoms then release the energy as light• If this light is passed through a prism the
element’s atomic emission spectrum is produced
ATOMIC EMISSION SPECTRA• An element’s atomic emission spectrum is the
set of wavelengths (colors) of light given off when atoms of that element are excited (e.g. heated)
• Each element’s emission spectrum is unique and can be used to identify the element– It is the element’s “fingerprint”
HOW DO WE KNOW WHAT THE STARS ARE MADE OF?
• Scientist analyze the light from a star using spectroscopes (similar to powerful prisms)
• Match the frequencies of light to the known spectra of the elements
• Stars are made of the same stuff as the rest of the Universe: 73% hydrogen, 25% helium, and the last 2% is all the other elements
LIGHT• Visible light is a type of electromagnetic radiation• All other electromagnetic radiation is invisible
• Electromagnetic (EM) radiation is energy that travels through space in the form of electromagnetic waves
• The electromagnetic spectrum encompasses all forms of electromagnetic radiations
increasing energy
BOHR’S MODEL OF THE ATOM• Bohr studied the emission spectrum
of hydrogen and developed his model of the atom
• The Bohr model describes the atom as a small, positively charged nucleus surrounded by electrons that travel in circular orbits around it
THE BOHR MODEL OF THE ATOM
• Each orbit or “ring” has a distinct energy levels or quantum number (n)– the bigger the number
the higher the energy
• Electrons in smaller orbits closer to the nucleus have less energy than electrons found in larger orbits farther from the nucleus
BOHR’S ATOM CONTINUED• The lowest energy state of an atom is its ground
state• When an atom gains energy (through heating for
example) it is in an excited state• in an excited state the electron absorbs the energy &
jumps to higher energy level • when it falls back down to its ground state it releases
excess energy in the form of light
• Because electrons jump between orbitals that have specific energy levels only certain colors can be given off
• This is how Bohr explained hydrogen’s emission spectrum
BOHR MODEL CONTINUED
Transitioncolor of light
emitted
n = 3 to n = 2 red
n = 4 to n = 2 blue-green
n = 5 to n = 2 blue
n = 6 to n = 2 violet
Wait!• Bohr’s model explained the emission
spectrum of Hydrogen, but it did not explain the emissions of any other element!
THE QUANTUM MECHANICAL MODEL OF THE ATOM
1. Electrons behave like waves2. It is impossible to know the
exact location or the velocity of an electron in an atom • (they don’t travel in circular
orbits around the nucleus)
3. Although it’s impossible to describe the exact location or describe how they are moving, the model describe the probability that electrons will be found in certain locations around the nucleus
ATOMIC ORBITALS• An atomic orbital is
a three-dimensional pocket of space around the nucleus that the electron is most likely to be found
• An electron has a 90% chance of being found within that space
• That is the best we can do!
ATOMIC ORBITALS
ORGANIZATION OF ATOMIC ORBITALS1. Principal energy level
(n)
2. Energy Sublevel
3. Orbitals
value: n = 1-7 s, p. d, f 1, 3, 5, 7
description:
-(n) indicates relative size and energy of orbital -As (n) increases so do energy and
size
-sublevels are labeled according to
shape:s: spherical p: dumbbell d/f: varied
-each sublevel has
a certain number of orbitals:
s = 1p =3d =5f = 7
-each orbital can hold two
electrons
QuickTime™ and aTIFF (Uncompressed) decompressor
are needed to see this picture.
ELECTRON CONFIGURATION
• An atoms electron configuration is the way an atom’s electrons are distributed among the orbitals of an atom
• The most state stable electron configuration is an atom’s ground state– Ground state: all electrons are in the lowest
possible energy state
• Electron configuration represented by writing symbol for the orbital and a superscript to indicate the number of electrons in the orbital Li: 1s2 2s1
increasingenergy
Energy
Each orbital can hold two electrons
2p
3p
1s
2s
3s
4s
5s4p
3d
4d
He Helium
2
4.003H
Hydrogen
1
1.008Li Lithium
3
6.941Be
Beryllium
4
9.012B
Boron
5
10.81C
Carbon
6
12.01N
Nitrogen
7
14.01O
Oxygen
8
16.00F
Fluorine
9
19.00Ne
Neon
10
20.18
The Pauli Exclusion Principle• The two electrons in an orbital
must spin in opposite directions
1s 2p2s
3s 3p
3d4s
HUND’S RULE• Negatively charged electrons repel each other, so:
– Electrons won’t pair up unless they have to– Once there is one electron in every orbital…the
pairing will begin!
2s1s
2p
1.
2s1s
2p
4.
2s1s
2p
2.
2s1s
2p
3.
Add an electron:
Add an electron:
Add an electron:
DRAW THE ORBITAL DIAGRAM AND WRITE THE
ELECTRON CONFIGURATION FOR:• Carbon
• Helium• Potassium
ELECTRON CONFIGURATION• The periodic table can be divided into four
distinct blocks based on valence electron configuration
• electron configuration explain the recurrence of physical and chemical properties
SHORTHAND (NOBLE GAS) NOTATION
• Shows electron filling starting from previous noble gas:– Na: 1s22s22p63s1
– Noble gas configuration: [Ne]3s1
WRITE THE FOLLOWING ELECTRON CONFIGURATIONS
IN NOBLE GAS NOTATION:• Fluorine• Titanium• Beryllium