600

03-600 Physical Inorganic Chemistry

This course synthesizes concepts from quantum mechanics, statistical thermodynamics and fundamental inorganic chemistry to explore advanced topics in transition-metal ion and complex chemistry and spectroscopy. The purity of materials, dynamic effects, crystallographic features, and surface adsorption phenomena will be discussed.
3

03-601 Kinetics and Reaction Mechanisms

This course explains the mechanisms of chemical reactions based on kinetic and thermodynamic principles to evaluate mechanistic arguments that govern the pathway from reactant to product. The course is meant to be broadly applicable to many types of chemistry— organic, physical, materials, etc.—and will focus on basic principles of reaction mechanisms and the subsequent energetics and dynamics present in the systems.
3

03-602 Advanced Biophysical Chemistry

This course synthesizes concepts from Biochemistry and Physical Chemistry to describe quantum mechanically the behavior of biomolecules and polymers and study the behavior of proteins and protein function. Physical principles and mathematical models will be used to describe protein behavior.
3

03-605 Applied Spectroscopy

This course applies a rigorous mathematical construct to fundamentals discussed in Spectroscopy and Physical Chemistry. The interaction of light and matter is developed with descriptions of the quantum mechanical aspects of light, the electric and magnetic properties of matter, group theory, perturbation theory and the time-dependent approach.
3

03-621 Materials Chemistry

This course discusses the design and characterization of materials that are the foundation for advanced technologies.  The course  covers the synthesis, structures, and properties of advanced materials, focusing on a range of topics with current societal importance (e.g. energy, computers, nanoscience, etc.).  Specific topics may include batteries, fuel cells, catalysts, metals, semiconductors, superconductors, magnetism, and polymers.
3

03-623 Supramolecular Chemistry

Supramolecular chemistry can be broadly defined as chemistry of the non-covalent bond. This course explores the field of supramolecular chemistry in the context of photochemistry and photophysics. More specifically, the control of photochemical reactions through the use of supramolecular structures will be studied.  Furthermore, the strategy for the synthesis of supramolecular systems and the reaction dynamics will be explored.
3

03-652 Computational Chemistry

Computational chemistry is the development and practical application – through high-performance computing – of quantum and classical mechanics (and informatics) to the study of chemical processes ranging from fundamental spectroscopic events in the gas phase to the nature of protein-drug interactions to the development of novel conducting materials.
3

03-680 Special Topics in Chemistry

This special topics course will be offered in either a lecture and/or lab format presenting topics of current interest in Chemistry. Course may be repeated for credit. Topics selected to enhance student learning and complement, not duplicate, material used in Readings, Seminar, and Thesis. Topics will vary.
1-3

Prerequisites

Consent of instructor.

03-685 Readings in Chemistry

Special topics in specific areas of chemistry tailored to meet the needs of individual students. Prerequisite: Consent of instructor. Readings selected to enhance student learning and complement, not duplicate, readings designed to meet Seminar and Thesis requirements.
1-3

Prerequisites

Consent of instructor.

03-696 Graduate Seminar

Students engage in journal reading, oral presentations, and critical discussions of topics in physics or related fields by invited speakers, faculty, and graduate students. Students must take this course for at least two semesters; however, only two credit hours can be applied toward the 30 credit hour degree requirement. Seminar will not replicate content of Readings or Thesis.
1

Prerequisites

Consent of instructor.

03-698 Master's Thesis

Students conduct research leading toward preparation of the Master's thesis. Students are required to register for this course during any term in which they are engaged in formal preparation of the master's thesis; however, the required six credit hours are the maximum number of credit hours applicable toward the 30 credit hour degree requirement.
1-6

Prerequisites

Consent of Instructor.