Lecture Number
|
Contents
|
1
|
Chapter 1: Introduction to Matter
|
2
|
Chapter 1: Units of
measure/dimensional analysis
|
|
Problem Set #1
|
3
|
Chapter 2: History/structure of the
atom
|
4
|
Chapter 2: Isotopic abundance and
nuclear particles
|
5
|
Chapter 2: Periodic table and
nomenclature
|
|
Problem Set #2
|
6
|
Chapter 3: Chemical equations and
chemical reactions
|
7
|
Chapter 3: Introduction to the mol
and Avogadro's number
|
|
Problem Set #3
|
8
|
Chapter 3: Stoichiometry and
limiting reagents
|
|
Problem Set #4
|
9
|
Chapter 3: Solution stoichiometry
|
|
Problem Set #5
|
10
|
Chapter 4: Introduction to
thermochemistry and definitions of heat, temperature,
etc.
|
11
|
Chapter 4: Calorimetry at constant
pressure and constant volume
|
|
Problem Set #6
|
12
|
Chapter 4: Introduction to enthalpy
and state functions
|
13
|
Chapter 4: Enthalpy of formation and
enthalpy of reaction
|
|
Problem Set #7
|
14
|
Chapter 5: The periodic table and
classification of elements
|
15
|
Chapter 5: Some chemical and
physical properties of the elements
|
|
Problem Set #8
|
16
|
Chapter 6: Introduction to light and
wave behavior
|
17
|
Chapter 6: Photoelectric effect and
the Bohr model of the atom
|
|
Problem Set #9
|
18
|
Chapter 6: Quantum mechanics and
quantum numbers
|
19
|
Chapter 6: Electronic structure of
the hydrogen atom
|
|
Problem Set #10
|
20
|
Chapter 7: Effective nuclear charge
and shielding in multi-electron atoms
|
21
|
Chapter 7: Electronic structure of
multi-electron atoms and electron configurations
|
22
|
Chapter 7: Periodicity in atomic
radii, ionization energy and electron affinity
|
|
Problem Set #11
|
23
|
Chapter 8: Ionic bonding model and
lattice energy
|
24
|
Chapter 8: Covalent boning model,
electronegativity
|
25
|
Chapter 8: Introduction to Lewis
structures
|
|
Problem Set #12
|
26
|
Chapter 8: Expanded octet, resonance
and bond dissociation energy
|
27
|
Chapter 8: Oxidation numbers and
nomenclature
|
|
Problem Set #13
|
28
|
Chapter 9:Introduction to VSEPR
|
29
|
Chapter 9: VSEPR, polarity and
dipole moments
|
30
|
Chapter 9: Sigma and pi bonding
|
31
|
Chapter 9: Hybridization
|
|
Problem Set #14
|
32
|
Chapter 10: Introduction to gases
and atmospheric pressure
|
33
|
Chapter 10: Boyle's, Charles' and
Avogadro's Law
|
34
|
Chapter 10: Ideal gas law
|
|
Problem Set #15
|
35
|
Chapter 10: Gaseous stoichiometry
and Dalton's Law
|
36
|
Chapter 10: Kinetic molecular model
of an ideal gas
|
37
|
Chapter 10: Effusion, diffusion and
real gases
|
|
Problem Set #16
|
38
|
Chapter 11: Kinetic molecular model
of a liquid and a solid and heating/cooling curves
|
39
|
Chapter 11: Introduction to vapor
pressure
|
40
|
Chapter 11: Clausius-Clapeyron
equation
|
|
Problem Set #17
|
41
|
Chapter 11: Intermolecular
attractive forces
|
42
|
Chapter 11: Introduction to solids
and cubic unit cells
|
43
|
Chapter 11: Closest-packing and
ionic solids
|
|
Problem Set #18
|
44
|
Review for Exam
|
45
|
Review for Exam
|
Tape Number
|
Contents
|
46
|
Chapter 12: Introduction to
Solutions and intermolecular attractive Forces
|
47
|
Chapter 12: Intermolecular
attractive forces and lattice energies
|
48
|
Chapter 12: Concentration: Molarity,
molality, mole fraction and weight percent
|
|
Problem Set #19
|
49
|
Chapter 12: Colligative properties:
vapor pressure and freezing point depression and boiling
point elevation
|
50
|
Chapter 12: Colligative properties;
ionic solutions
|
51
|
Chapter 12: Osmotic pressure and
colloids
|
|
Problem Set #20
|
52
|
Chapter 13: Introduction to chemical
kinetics, initial, instantaneous and average rates
|
53
|
Chapter 13: Differential rate laws
and method of initial rate
|
|
Problem Set #21
|
54
|
Chapter 13: Integrate rate law for
simple reactions following first order kinetics
|
55
|
Chapter 13: Integrate rate law for
simple reactions following second order kinetics
|
|
Problem Set #22
|
56
|
Chapter 13: Activation energy and
the Arrhenius equation
|
57
|
Chapter 13: Energy profile diagram
and reaction mechanisms
|
58
|
Chapter 13: Reaction mechanisms and
catalysis
|
|
Problem Set #23
|
59
|
Chapter 14: Introduction to chemical
equilibrium...macroscopic
|
60
|
Chapter 14: Introduction to chemical
equilibrium...microscopic
|
61
|
Chapter 14: Write equilibrium
expressions and deermine equilibrium constants
|
|
Problem Set #24
|
62
|
Chapter 14: Calculate the
equilibrium concentrations given the equilibrium
concstant and the initial concentration of a reactant(s)
|
63
|
Chapter 14: Le Chatelier's principle
|
64
|
Chapter 14: Temperature dependence
of the equilibrium constant and the relationship between
equilibrium and rate constants
|
|
Problem Set #25
|
65
|
Chapter 15: Define Arrhenius acids
and bases and pH
|
66
|
Chapter 15: Define Brnsted-Lowry
acid and Brnsted-Lowry base
|
67
|
Chapter 15: Calculate the
equilibrium constatn for a weak acid and base, and
calculate the pH of a solution of a weak or weak base
|
|
Problem Set #26
|
68
|
Chapter 15: Calculate the pH of a
polyprotic acid
|
69
|
Chapter 15: Calculate the pH of a
salt solution
|
70
|
Chapter 15: Discuss the relationship
of molecular structure to strength of acid
|
|
Problem Set #27
|
71
|
Chapter 16: Introduce common ions
systems and calculate their pH
|
72
|
Chapter 16: Calculate the pH for
points on the titration curve for the neutralization of a
strong acid and strong base
|
73
|
Chapter 16: Calculate the pH for
points on the titration curve for the neutralization of a
weak acid and strong base
|
|
Problem Set #28
|
74
|
Chapter 16: Introduce buffers and
how to calculate the pH of a buffer solution
|
75
|
Chapter 16: Calculate the pH of a
buffer after adding a strong acid and a strong base
|
76
|
Chapter 16: Introduce solubility and
solubility product constant
|
77
|
Chapter 16: Calculate the solubility
of an insoluble salt and predict whether a precipitation
will occur when mixing aqueous solutions of soluble salts
|
|
Problem Set #29
|
78
|
Chapter 17: Review the first law of
thermodynamics, heat of formation and heat of reaction
|
79
|
Chapter 17: Introduce the second law
of thermodynamics, entropy and entropy of reaction
|
80
|
Chapter 17: Free energy, and the
importance of enthalpy, entropy and temperature to
spontaneity
|
81
|
Chapter 17: Free energy at standard
and nonstandard conditions
|
|
Problem Set #30
|
82
|
Chapter 18: Introduce oxidation,
reduction and oxidizing and reducing agents
|
83
|
Chapter 18: Balancing
oxidation-reduction reaction
|
84
|
Chapter 18: Draw voltaic cells, emf
and standard cell potentials
|
|
Problem Set #31
|
85
|
Chapter 18: Calculate Eû and relate
Eû to spontaneity
|
86
|
Chapter 18: Application of the
Nernst equation
|
87
|
Chapter 18: Discuss electrochemical
reactions in batteries and corrosion
|
|
Problem Set #32
|
88
|
Chapter 18: Electrochemical reaction
in the chemical industry
|
89
|
Chapter 18: Quantitative
applications in electrolysis reactions
|
|
Problem Set #33
|
90
|
Review for Exam
|