56:160:506 Materials Chemistry (3)
Introduction to the study of materials, including the relationships between the structures and properties of materials.

56:160:508 Organic Mechanisms: Nucleophiles and Bases (3)
An introduction to nucleophilic organic reaction mechanisms. How to correctly represent a reaction mechanism. Instruction in critical thinking and problem solving to elucidate and critically evaluate organic reaction mechanisms involving nucleophiles and bases. 
Prerequisite: 50:160:336 or equivalent.

56:160:509 Organic Mechanisms: Electrophiles and Acids (3)
An introduction to electrophilic organic reaction mechanisms and what they mean. How to correctly represent a reaction mechanism. Instruction in critical thinking and problem solving to elucidate and critically evaluate organic reaction mechanisms involving electrophiles and acids.
Prerequisite: 50:160:336 or equivalent.

56:160:510 Organic Mechanisms: Radicals (3)
An introduction to radical organic reaction mechanisms. How to correctly represent single electron movement in a mechanism. Instruction in critical thinking and problem solving to elucidate and critically evaluate radical mechanisms. This course focuses on radical, single electron, and photochemical reactions.
Prerequisite: 50:160:336 or equivalent.

56:160:511 Advanced Organic Chemistry I (3)
Advanced survey of organic chemistry. Molecular orbital theory, orbital symmetry correlations, structure and stereochemistry of organic molecules, chemistry of reactive intermediates (including free radicals), photochemistry, structure-reactivity relationships, and molecular rearrangements.
Prerequisites: 50:160:335,336, or equivalent.

56:160:512 Advanced Organic Chemistry II (3)
Advanced survey of synthetic transformations and reaction mechanisms.

56:160:513 Organic Analysis (3)
Interpretation and use of infrared, visible, and ultraviolet spectroscopy; mass spectrometry; and nuclear magnetic resonance for the identification of organic compounds. Combination with separation techniques is included.

56:160:514 Introduction to Molecular Modeling (3)
Introduction to the use of computer-assisted molecular modeling techniques for the study of chemical problems; lectures on theoretical principles; instruction in use of modern modeling programs; and computer projects involving solution of chemical problems.

56:160:515 Polymer Chemistry (3)
Introduction to the chemistry of macromolecules, aimed at understanding the relationship between molecular structures and properties of high polymers. This course includes an overview of polymer nomenclature, molecular weight properties, types of polymerization, structure (morphology), characterization, and testing of polymers. Prerequisite: 50:160:336 or equivalent.

56:160:519 Fluorocarbons (3)
Provides a survey of the chemistry of fluorinated organic molecules emphasizing a broad mechanistic basis. Areas covered include comparisons of fluorinated and hydrocarbon compounds; introduction of organofluorine chemistry; preparation of highly fluorinated molecules; partial and selective fluorination, influence of fluorine and fluorocarbon groups on reaction centers; nucleophilic displacement and elimination from fluorocarbon systems: polyfluoroalkanes, -alkenes, and -alkynes; polyfluoroaromatic compounds; organometallic compounds, and 19F nuclear magnetic resonance.

56:160:522 Molecular Spectroscopy (3)
Principles of electronic and vibrational spectroscopy of polyatomic molecules. Emphasis on the ways in which spectra yield information about molecular properties.

56:160:531,532 Advanced Inorganic Chemistry I,II (3,3)
An introduction to the discipline of inorganic chemistry including periodic properties, bonding theory, solids, redox, acid/base chemistry, and coordination chemistry. Semester two includes details on reaction mechanisms, spectroscopy, magnetism, and stereochemistry, as applied to inorganic compounds with an emphasis on coordination compounds of transition metals.

56:160:533 Symmetry Applications in Chemistry (3)
Principles and applications of molecular and crystal symmetry. Topics include point groups, character tables, representations of groups, and other aspects of group theory; symmetry applications in structure and bonding; molecular orbital theory and ligand field theory; and selection rules for electronic, vibrational, and rotational spectroscopy.

56:160:533 Symmetry Applications in Chemistry (3)
Principles and applications of molecular and crystal symmetry. Topics include point groups, character tables, representations of groups, and other aspects of group theory; symmetry applications in structure and bonding; molecular orbital theory and ligand field theory; and selection rules for electronic, vibrational, and rotational spectroscopy.

56:160:534 NMR Spectroscopy (3) 
Introduction to the physical principles underlying one of the most widespread and useful tools for chemical analysis. Starting from the descriptions of the phenomenon, a physical picture of NMR experiments in liquids will be developed and the connection between the concepts and actual laboratory practices will be emphasized. The course will include:  roles of chemical shifts, couplings, and relaxation effects in analysis of chemical structure and bonding. Two-dimensional NMR will explain what happens, how the experiment is selected, and how data is interpreted. A survey of solid state NMR and some emerging technologies will be discussed.  Prerequisites: 50:160:326 and 346, or equivalent.

56:160:541 Electrochemistry (3)
Theory and applications of electrochemical principles and techniques, including voltametry, potentiometry, chronopotentiometry, and spectroelectrochemistry.

56:160:545 Radiochemistry and Radiation Chemistry (3)
Interactions of ionizing radiation with matter and the resulting radiation-induced chemical reactions: excitation, ionization, free radical formation and recombination; chemical consequences of nuclear reactions; and “hot atom” chemistry. Prerequisite: 50:160:415 or equivalent.

56:160:575,576 Special Topics in Chemistry (BA,BA)
Subject matter varies according to the interest of the instructor and is drawn from areas of current interest.

56:160:601,602 Seminar in Chemistry (1,1)
A variety of topics of current interest regularly presented and discussed by students, faculty, and invited experts. Full-time graduate students must give an oral presentation annually. First-year, full-time students (Plan A: Thesis) must present their proposed research project to the graduate faculty before spring break. Students who anticipate degree completion (Plan A: Thesis or Plan B: Nonthesis) must present by mid-April for a May-dated degree (early September for an October-dated degree).

56:160:619,620 Individual Studies in Chemistry (BA,BA)
Designed for students conducting original projects in chemistry either as part of the thesis research or for the nonthesis option. The project is designed and conducted in consultation with a sponsor from, or designated by, the graduate faculty. Nonthesis students complete 2 credits culminating in a written term paper and oral presentation before the graduate faculty. Generally thesis students complete at least 4 credits culminating in a written thesis and seminar presentation.

56:160:701,702 Research in Chemistry (BA,BA)
Open only to students working on research for the thesis. Prerequisite: Permission of thesis adviser.

56:160:800 Matriculation Continued (0)
Continuous registration may be accomplished by enrolling for at least 3 credits in standard courses, including research courses, or by enrolling in this course for 0 credits. Students actively engaged in study toward their degree who are using university facilities and faculty time are expected to enroll for the appropriate credits.

Biochemistry Courses

56:115:511,512 Biochemistry I, II (3,3)
Study of the structure and function of proteins and enzymes. Analysis of the chemistry of carbohydrates, lipids, and nucleic acids. Detailed survey of metabolic pathways, with an emphasis on regulation.

56:115:522 Protein Structure and Function (3)
Basic structural principles of polypeptides, mechanisms of enzyme catalysis, biosynthesis and degradation of proteins, biophysical techniques used in the determination of peptide and protein structure, protein folding, protein engineering, catalytic antibodies, peptide and protein de novo design, solid-phase peptide synthesis, and interactive computer graphics modeling.

56:115:524 Natural Product Chemistry (3)
Survey of carbohydrates, amino acids, peptides, biopolymers, heteroaromatics, terpenes, steroids, fatty acids, and alkaloids.

56:115:575,576 Special Topics in Biochemistry (BA,BA)
Subject matter varies according to the expertise of the instructor and is drawn from areas of current biochemical interest.

56:115:619,620 Individual Studies in Biochemistry (BA,BA)
Designed for students conducting original projects in chemistry in lieu of a research thesis. The project is designed and conducted in consultation with a sponsor from, or designated by, the graduate faculty.

56:115:701,702 Research in Biochemistry (BA,BA)
Open only to students working on research for their thesis. Prerequisite: Permission of thesis adviser.