Fall 2010 Cumulative
Outline
(This will slide around abit as the semester proceeds to
accommodate shifts in emphasis. After each lecture, the
"Lecture X" hyperlink will connect to that lecture's
slide collection. Previews may be found via the
"Main Index" under "Preview". When lecture
material has corresponding text material, the Chapter and
possible Section are indicated in [green]. Be aware that parts of
the outline may have no corresponding reading in the text.
Lecture Slides 1. History [Chapter
2]
- The
first 2000 years
- Stoichiometry
Laws
·
- Conservation
of Mass
- Law
of Definite Proportions
- Law
of Multiple Proportions
- Law
of Multiple Proportions illustrated
- Dalton's
Postulates and Atomic Theory
- Dalton's
"Postulate of Simplicity"
Lecture Slides 2. History
- Avogadro's
Law (Hypothesis) [p. 20]
- Cannizzaro's
Stoichiometric Analyses
- Early
recognition of "Periodicity"
Energies
- Kinetic
energy
- Potential
energy (and forces)
- Internal
energies (rotation and vibration)
- Light
[Chapter 12]]
- H-atom
line spectra (emission and absorbtion)
Masses
Lecture Slides 3.
Masses (molecules)
Problems with some results of physical measurements [Chapter
12]
- Line
spectra
- Photoelectric
Effect
- Blackbody
Radiation (and the ultraviolet catastrophe)
Physics puzzles "solved" by quantization
- Blackbody
radiation, Planck, E=hv, energy jumps
- Photoelectric
Effect, Einstein, the photon
- Line
spectra, Bohr's Planetary Model, quantized angular
momentum
(Old Quantum Theory)
Physics puzzles "solved" by quantization (continued)
Line spectra, Bohr's Planetary Model, quantized angular
momentum [Section 12.4]
(New Quantum Theory)
- deBroglie
and wave-particle duality of matter (Section 12.2)
Lecture Slides 4. (Old Quantum
Theory)
(New Quantum Theory)
- deBroglie
and wave-particle duality of matter (Section 12.2)
Wave Nature of Matter
- Particle-in-a-box
(Section 12.6)
- one
dimension
- two
dimenstions
- three
dimensions
- Schrodinger
wave equation (concept), amplitude squared =
local probability densities (Section 8.6)
- Schrodinger's
Wave Equation applied to the hydrogen atom [Section 12.7]
- n,
principal quantum number
- l,
angular momentum or shape quantum number
- ml, magnetic or orientation
quantum number
Lecture Slides 5. (New
Quantum Theory)
Geometries [12.9]
More outcomes of wave-particle duality
- (Heisenberg's)
Uncertainty Principle [p.539]
- simultaneous
precise measurements restrictions
- paths
or orbits of particles are not legitimate
topics of discussion
- Radial
density distributions and electron density plots
Lecture Slides 6. More outcomes
of wave-particle duality
- Radial
density distributions and electron density plots
- screening
and penetration of electrons in the same
shell
Many-electron systems
- (Pauli)
Exclusion Principle [Section
12.10]
- Effective
nuclear charge [Section 12.11]
- Photoelectron
spectra of atoms
- Hund's
Rule [Section 12.13]
- paramagnetism
Lecture Slides 7. The Periodic
Table (continued)
- Excited states
- Building the Periodic Table
- Electron configurations (exceptions)
- Sizes [pp. 577,8]
- Isoelectronic species
Lecture Slides 8. Periodic Table
(continued)
- Ionization energies
- Electron affinities[12.15]
Lecture Slides 9. Exam I Review
Lecture Slides 10. Molecules
Electronegativity [13.2]
Molecular Structure
Lewis Structures [13.10]
- Valence electrons (Main groups)
- Octet Rule
- Structural isomers
Lecture Slides
11. Lewis Structures [13.10]
- Formal
charge and preferred structures [13.12]
- Exceptions to the Octet Rule [13.12]
- Incomplete octets
- Odd electron numbers
- Expanded octets (hypervalency)
Lecture Slides12. Molecular
Structure
Resonance (Benzene puzzles)
Resonance [13.12]
- Equivalent
preferred contributors
- Bond
order
Lecture Slides 13. Lewis
structures
Dipole moments and partial ionic character
Lecture Slides 14.
Line Structures
Acid strengths and pK's
Lecture Slides 15.
Acid strengths and pK's
- Oxoacids
- Resonance stabilization
- Carboxylic acids
Molecular Geometries
VSEPR Model [13.13]
- Steric
number (and coordination number)
- Electronic
geometries
- (Ideal)
Molecular geometries
Lecture Slides 16. Molecular
Geometries
VSEPR Model [13.13]
- (Ideal)
Molecular geometries
- Central atom with lone pairs
Distortions from ideal geometries
- effect
of lone pairs vs bonding pairs
- effect
of multiple bonds
- effect of lone single electrons
Lecture Slides 17 .Molecular
Geometries
Distortions from ideal geometries
- effect
of electronegativity
Dipole Moments in Polyatomic Molecules
- Rigidity about double bond
- Molecular dipoles from "bond" dipoles
- Geometrical isomers
- Free and restricted rotations about bonds
Lecture Slides 18. Review for
Exam II
Lecture Slides 19. Quantum
Theory of the Chemical Bond
Molecular orbitals (in "homonuclear diatomic
molecules" [14.2]
- Approximated by combinations of atomic orbitals
- Constructive and
destructive interference effects
- Combining 1s atomic
orbitals to get molecular orbitals
- "Sigma" bonding molecular
orbital
- "Sigma" antibonding
molecular orbital
- Combining 2p atomic orbitals
- "Sigma" bonding molecular
orbital
- "Sigma" antibonding
molecular orbital
Lecture Slides 20. Quantum
Theory of the Chemical Bond
Molecular orbitals (in "homonuclear diatomic
molecules") [14.3]
- Molecular energy level diagrams
- Building up electron configurations
- Bond order
Lecture Slides 21. Quantum
Theory of the Chemical Bond
Molecular Orbitals (factors to consider)
- Importance of energy match vs mismatch
- Importance of net overlap
Heteronuclear diatomic molecules [14.4]
Lecture
Slides 22. Quantum
Theory of the Chemical Bond
Molecular Orbitals
- Polyatomic molecules
Hybrid atomic orbitals [14.1]
Lecture
Slides 23. Quantum Theory of the Chemical Bond
Molecular Orbitals in Polyatomic Molecules
- Molecular orbitals from combinations of hybrid atomic
orbitals
- The rigid double bond
- The freely rotating single sigma bond
- 1,3 butadience and delocalized moleculal orbitals
Lecture Slides 24. Molecular
Orbitals in Polyatomic Molecules (Delocalized Bonds)
- 1,3 butadiene and the use of
"partial bond order per electron"
- benzene
- ozone
Lecture Slides 25. Molecular
Orbitals in Polyatomic Molecules (Delocalized Bonds)
Triatomic molecules
- Ozone
- Carbon dioxide
- Strained bonds
Energy levels and the particle-in-a-box model
- conjugated systems
- particle-in-a-box levels
- light absorption transitions
Lecture Slides 26. Delocalized
Molecular Orbitals
Energy levels and the particle-in-a-box model
- conjugated systems
- particle-in-a-box levels
- light absorption transitions
- retinal
- Metallic bonds [pp. 797-8]
Lecture
Slides 27. Review
for Exam III
Lecture
Slides 28. Intermolecular
interactions
Real gases (Van der Waals) [5.10]
- Excluded volume effect
- Intermolecular attractions
Lecture Slides
29. Intermolecular
Interactions (condensed phases)Real gases (Van der Waals) [16.1, 2]
Induced dipoles
Van der Waals interactions
- Permanent dipoles
- Temporary (induced) dipoles
- Boiling points, melting points, densities
- Effects of size
- Effects of shape
Lecture Slides 30.
Intermolecular Interactions (condensed phases)
Van der Waals interactions
- Hydrogen Bonding
- Molecular Basis of Solubility
Lecture Slides 31.
Intermolecular Interactions
- Molecular Basis of Solubility
Oxidation Numbers
Lecture Slides 32.
Oxidation Numbers
Transition Metal Chemistry
- Tramsition metal ion electron configurations [19.1]
- Coordination complexes [19.3]
- Isomers [19.4]
Lecture Slides 33. Transition
metal complexes
Stereoisomers [19.4]
Geometrical isomers
- Square planar geometries
- Octahedral geometries
Optical isomers
Observations to explain
- Colors
- Magnetic Properties
- Stability
Crystal Field Theory [19.6]
Lecture Slides 34. Transition
Metal Complexes
Crystal Field theory
- Distorting the octahedral geometry
- Square Planar geometry
- Tetrahedral geometry
Ligand Bonding to central ion's hybrid orbitals
Lecture Slides 35.
Review for Exam IV
Lecture Slides 36.
Hemoglobin
- Bonding of heme Fe2+ to O2
vs CO
- Sizes of transition metal ions
- Role of protein in hemoglobin