Post on 12-Feb-2016
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CHAPTER 12 – CHEMICAL BONDING
CHEMICAL BOND – A force that holds two or more atoms together as a unit
Individual atoms will naturally bond together to achieve a lower energy state (to be more stable)
3B-1 (of 42)
TYPES OF BONDS
Metal atoms easily lose electrons forming positive ions, and nonmetal atoms easily gain electrons forming negative ions
1) METAL ATOMS AND NONMETAL ATOMS
3B-2
IONIC BOND – The electrostatic attraction between positive and negative ions
Ionic bonding forms giant crystalline networks containing billions of positive and negative ions that are strongly attracted together
Ionic bonding exists between metal and nonmetal ions
+
Fe atoms O atoms (molecules) Fe ions and O ions
Elemental Iron Elemental Oxygen Rust
3B-3
Nonmetal atoms attract each other’s valence electrons, and share the valence electrons between pairs of atoms
Covalent Bond – The electrostatic attraction of shared electrons to the nuclei of bonding nonmetal atoms
Covalent bonding forms individual units called molecules, and while the atoms that covalently bond together strongly attract each other, the molecules that are created weakly attracted each other
Covalent bonding exists between nonmetal atoms
2) NONMETAL ATOMS
3B-4
3B-5
+
C atoms Cl atoms (molecules) CCl4 molecules
Elemental Carbon Elemental Chlorine Carbon Tetrachloride
NONPOLAR COVALENT BOND – A bond in which 2 atoms are sharing electrons equally
POLAR COVALENT BOND – A bond in which 2 atoms are sharing electrons unequally
IONIC BOND – A bond in which two atoms have transferred electrons
Picture
3B-6
ELECTRONEGATIVITY – The attraction of an atom for shared electrons
The difference in the EN’s of 2 atoms tells the type of bond they make
Atom with the highest EN? Atom with the lowest EN?
EN Difference Bond
0.00.1 to 1.61.7 to 3.3
Nonpolar CovalentPolar CovalentIonic
3B-7
N-N Bond
EN for N = 3.0
3.0 – 3.0 = 0.0
Nonpolar Covalent Bond
3B-8
Polar covalent bonds have partially positive and a partially negative ends
DIPOLE MOMENT – The amount of separation of the positive and negative charges in a bond
C-O Bond
EN for C = 2.5, O = 3.5
3.5 – 2.5 = 1.0
Polar Covalent Bond
H-S Bond
EN for H = 2.1, S = 2.5
2.5 – 2.1 = 0.4
Polar Covalent Bond
C –– O+ d-d
H –– S+ d-d
DIPOLE MOMENT ARROW – Shows the direction of the dipole moment, pointing toward the negative end of the bond
C –– O H –– S
3B-9
Na-Cl Bond
EN for Na = 0.9, Cl = 3.0
3.0 – 0.9 = 2.1
Ionic Bond
Na+ Cl-
3B-10
BONDING IN IONIC COMPOUNDS
Atoms form ions to obtain a stable, octet electron arrangement
Sodium chloride
Na . .. Cl :
. .
A sodium chloride crystal is a symmetrical array of sodium and chloride ions in a 1:1 ratio
EMPIRICAL FORMULA – The simplest whole number ratio of atoms of different elements in a compound
Empirical Formula: NaCl
+ -
3B-11
Magnesium fluoride
Mg . . . F :
. .
. . . F :
. .
+ -2 -
Empirical Formula: MgF2
3B-12
Potassium nitride
Empirical Formula:
3B-13
SIZES OF ATOMS AND IONS
Positive ions are smaller than their neutral atoms and negative ions are bigger than their neutral atoms
Na atom Cl atom
Na+ ion Cl- ion
3B-14
1) The more energy levels an atom or ion has the larger it will be
2) With the same number of energy levels, the more protons an atom or ion has the smaller it will be
Li F Na Cl
ElectronsEnergy LevelsProtonsBig to Small
3233rd
9294th
113
111st
173
172nd
21
4th
1029
2nd
102
113rd
183
1st
Li+ F- Na+ Cl-
ISOELECTRONIC – Ions or atoms with the same number of electrons
Sizes of atoms or ions are determined by
3B-15
BONDING IN COVALENT MOLECULES
Atoms share electrons to obtain a stable, octet (or duet) arrangements
Water (H2O)
H . . . O :
.
H
. .H – O :
H
← LONE PAIR← BONDING PAIR
LEWIS STRUCTURE – A diagram using electron dot notation to show how the valence electrons are arranged among bonded atoms
3B-16
To draw a proper Lewis Structure:
1 – Add up the valence e-s for all of the atoms in the molecule or ion
2 – Draw a skeletal structure by using pairs of electrons to make bonds
4 – If octets are not produced, make the atoms that have octets share more e- pairs with atoms that do not have octets
3 – Complete octets (or duets for H) for all atoms, outer atoms first, using the remaining valence e-s
3B-17
Sulfur dichloride, SCl2
6 + 7 + 7 = 20 valence e-s
Cl S Cl
3B-18
Phosphorus tribromide, PBr3
3B-19
Ammonia, NH3
5 + 1 + 1 + 1 = 8 valence e-s
H N H
H
3B-20
Methane, CH4
3B-21
Fluorine, F2
7 + 7 = 14 valence e-s
F F
SINGLE BOND – One shared pair of e-s between two atoms
3B-22
Oxygen, O2
6 + 6 = 12 valence e-s
O O
DOUBLE BOND – Two shared pairs of e-s between two atoms
3B-23
Nitrogen, N2
5 + 5 = 10 valence e-s
N N
TRIPLE BOND – Three shared pairs of e-s between two atoms
3B-24
Hydrogen cyanide, HCN
1 + 4 + 5 = 10 valence e-s
H C N
Carbon disulfide, CS2
3B-25
Sulfate, SO42-
6 + 4(6)
O
O S O
O
+ 2 = 32 valence e-s
2-
Ammonium, NH4+
H
H N H
H
5 + 4(1) - 1 = 8 valence e-s
+
3B-26
Ozone, O3
6 + 6 + 6 = 18 valence e-s
O O O O O Oor
O O OO O O ↔
RESONANCE – When more than one Lewis structure can be drawn for a molecule or ion
RESONANCE STRUCTURES – The Lewis structures that can be drawn for the molecule or ion
The real ozone molecule is a average of its resonance structures
3B-27
O O OO O O ↔
O O O
2 “1½” bonds
3B-28
MOLECULAR SHAPE
VSEPR THEORY (Valence Shell Electron Pair Repulsion) – All atoms and lone pairs attached to a central atom will spread out as far as possible to minimize repulsion
A Lewis structure must be drawn to use the VSEPR Theory
3B-29
H
H C H
H
STERIC NUMBER (SN) – The sum of the bonded atoms and lone pairs on a central atom
The steric number of carbon is 4 (SN = 4): 4 bonded atoms and no lone pairs
Tetrahedral
Bond angle is 109.5°
H
C
HH H
3B-30
H N H
H
The steric number of nitrogen is 4 (SN = 4): 3 bonded atoms and 1 lone pairs
Trigonal Pyramidal
Bond angle is 108° N
HH H
3B-31
The steric number of oxygen is 4 (SN = 4): 2 bonded atoms and 2 lone pairs
Bent
Bond angle is 105° O
HH
. .H – O :
H
3B-32
Formaldehyde, H2CO
1 + 1 + 4 + 6
H
H C O
= 12 valence e-s
The steric number of carbon is 3 (SN = 3): 2 bonded atoms and 1 lone pairs
Trigonal Planar
Bond angle is 120°
O
H HC
3B-33
SiS2
4 + 6 + 6
S Si S
= 16 valence e-s
The steric number of silicon is 2 (SN = 2): 2 bonded atoms and 0 lone pairs
Linear
Bond angle is 180° S Si S
3B-34
SN
4
4
4
3
3
2
Atoms
4
3
2
3
2
2
Shape
Tetrahedral
Trigonal Pyramidal
Bent (109.5°)
Trigonal Planar
Bent (120°)
Linear
3B-35
Lone Pairs
0
1
2
0
1
0
MOLECULAR POLARITY
A BOND is polar if it has a positive end and a negative end
A MOLECULE is polar if it has a positive end and a negative end
3B-36
To determine if a molecule is polar or nonpolar:
1) Draw the correct Lewis structure
2) Draw its correct shape
3) Use EN’s to determine if the BONDS in the molecule are polar or nonpolar
4) For the polar bonds, label the positive and negative ends with δ+ and δ-
5) If a line can be drawn separating all δ+’s from all δ-’s, the molecule is polar, it not its nonpolar
. .H – O :
H
O
HH
δ+
δ-
δ+δ-
EN’s: O = 3.5, H = 2.1
3.5 – 2.1 = 1.4 the O-H BONDS are polar
All of the δ+’s can be separated from all of the δ-’s, the H2O MOLECULE is polar
3B-37
δ+
δ-
δ+
δ-
EN’s: N = 3.0, H = 2.1
3.0 – 2.1 = 0.9 the N-H BONDS are polar
All of the δ+’s can be separated from all of the δ-’s, the NH3 MOLECULE is polar
H N H
H
N
HH H δ+
δ-
3B-38
F
F C F
F
Carbon tetrafluoride, CF4 4 + 4(7) = 32 valence e-s
F
C
FF F
EN’s: C = 2.5, F = 4.0
4.0 – 2.5 = 1.5 the C-F BONDS are polar
All of the δ+’s cannot be separated from all of the δ-’s, the CF4 MOLECULE is nonpolar
δ+
δ-
δ-δ+
δ-
δ+
δ-δ+
3B-39
REVIEW FOR TEST
Electromagnetic Radiation, Photons
Ground State, Excited State
Orbital
Energy Levels
Sublevels
Orbital Notation
Electron Configuration Notation
Electron Dot Notation
Valence Electrons
Octet
Electron Pair
2B-40
REVIEW FOR TEST
Periodic Trends in
Metal, Nonmetal Activity
Atomic Radii
Ionization Energy
Electron Affinity
Ionic Bonds, Covalent Bonds
Electronegativity
Bond Polarity from Electronegativities
Ion Sizes
2B-41
REVIEW FOR TEST
Lewis Structures for
Ionic Compounds
Covalent Compounds
Resonance
Molecular Shapes
Molecular Polarity
2B-42