Submitted by Anne Bentley / Lewis & Clark College on Wed, 01/10/2018 - 18:20
My Notes
Specific Course Information
Course Area and Number
Chem 420
Institution
Lewis & Clark College
Location
Portland, OR
Textbook
Inorganic Chemistry (5th ediction), Miessler, Fischer & Tarr
Course Meetings and Time
Number of meetings per week
3 meetings / week
Time per meeting (minutes)
60 min / meeting
Number of weeks
14 weeks
Lab Associated
Yes, standalone
Average Class Size
5 to 15
Typical Student Population
The students enrolled in this course over the past ten years have been nearly 100% chemistry majors. (With one or two biochemistry / molecular biology majors.)
Categories
Prerequisites
Physical Chemistry: Quantum Mechanics
Corequisites
No Corequisites
Course Level
Upper Division/Graduate
Topics Covered
Acid-base chemistry
Bioinorganic chemistry
Bonding models: Discrete molecules
Bonding models: Extended systems
Chemical literature
Coordination chemistry
Descriptive chemistry
Electronic spectroscopy
Electronic structure
Extended structure
Group theory & applications
Main group chemistry
Materials chemistry
Molecular structure
Organometallic chemistry
Periodic trends
Solids & solid state chemistry
Symmetry
Description

Modern concepts of inorganic and transition-metal chemistry
with emphasis on bonding, structure, thermodynamics, kinetics and
mechanisms, and periodic and family relationships. Atomic structure,
theories of bonding, symmetry, molecular shapes (point groups), crystal
geometries, acid-base theories, survey of familiar elements, boron
hydrides, solid-state materials, nomenclature, crystal field theory,
molecular orbital theory, isomerism, geometries, magnetic and optical
phenomena, spectra, synthetic methods, organometallic compounds,
cage structures, clusters, lanthanides, actinides.

File attachments
chem420_2017.pdf
Learning Goals

By the end of this course, students will be able to:

1.  Use concepts from quantum theory and atomic orbitals to explain periodic trends in atomic properties and relate these to inorganic chemistry.
 

2.  Predict the structure and using an appropriate model, describe the bonding in main group molecules.

3.  Identify the symmetry operations and the point group of a molecule.

4.  Apply tools from symmetry and group theory to solve problems involving vibrational spectroscopy and molecular orbital theory.

5.  Extend acid-base concepts to inorganic systems and use different models to predict chemical reactivity.

6.  Use Latimer, Pourbaix, and Frost diagrams to predict the electrochemical activity of a system.

7.  Describe the structures and properties of common crystalline and ionic solids.

8.  Use crystal field or MO theory to explain the electronic structure and magnetism of transition metal complexes.

9.  Read and discuss an article from the inorganic chemistry primary literature.

 

How the course is taught
Mostly lecture, some small groups, daily homework problems
VIPEr LOs used in course
First day activity
First Day Review of Atomic Orbitals
H atom radial factors
Fivefold Bonding in Cr(I) Dimer
The N5+ Cation: Explosive Chemistry and Raman Analysis (Christe)
Werner From Beyond the Grave
Symmetry Scavenger Hunt
First Isolation of the AsP3 Molecule
Towards "Personalized Solar Energy": An Inexpensive Oxygen-Evolving Catalyst
Dissecting Catalysts for Artificial Photosynthesis
Fe2GeS4 Nanocrystals for Photovoltaics
Solar-Powered Oxidation of Water
Teaching General Chemistry: A Materials Science Companion
Putting electrochemistry to use: Design of new lithium-ion battery anodes
Evaluation
Grading Scheme
Midterm exams (3) 45%
Final exam 20%
Problems 20%
Journal article assignment 15%
Creative Commons License
Attribution, Non-Commercial, Share Alike CC BY-NC-SA
Claude Mertzenich / Luther College

Do you know of any listing of texts for advanced inorganic chemistry?

Fri, 06/08/2018 - 16:37 Permalink