This course is designed to give you a quick review and understanding of traditional and modern synthetic reaction mechanisms and principles involving heterocyclic molecules. The course will primarily cover the synthesis and general reactivities of aromatic heterocyclic ring systems. Must have successfully completed Organic Chemistry II (CHEM 2420).

Studies the theory and application of instrumental techniques in solving organic structural problems. Topics include ultraviolet and infrared absorption spectroscopy, nuclear magnetic resonance, mass spectrometry, rotatory dispersion, and circular dichroism.

For students interested in the properties & phenomena of atomic, molecular, & nanoscale matter. The foundational ideas of quantum mechanics are introduced & tools for exact & approximate solutions of the Schrodinger Equation are developed. Model systems, such as particle in a box, harmonic oscillator, hydrogen atom, hydrogen ion & molecule, crystalline solids, as well as time-dependent phenomena, such as spectroscopy, tunneling, and scattering.

This course provides an introduction to statistical mechanics for graduate students or highly advanced undergraduates. The course begins with a review of thermodynamics and an introduction to the fundamental assumptions of equilibrium statistical mechanics, continues on to examine both non-interacting and interacting systems of interest, and finally introduces the basic concepts of non-equilibrium statistical mechanics.

Introduces the practice and theory of modern chemical kinetics, emphasizing reactions occurring in gases, liquids, and on catalytic surfaces. Develops basic principles of chemical kinetics and describes current experimental and analytic techniques. Discusses the microscopic reaction dynamics underlying the macroscopic kinetics in terms of reactive potential energy surfaces. Develops statistical theories of reactions that simplify the description of the overall reaction dynamics. Includes the transition state theory, Rice-Ramsperger-Kassel-Marcus (RRKM) theory for unimolecular reactions, Kramers' theory, Marcus electron transfer theory, and information theory. Presents current topics from the literature and illustrates applications of basic principles through problem-solving exercises. Prerequisite: Undergraduate physical chemistry or instructor permission.

Theory and applications of magnetic resonance spectroscopy. Topics include theoretical principles of nuclear magnetic resonance (NMR) spectroscopy, practical aspects of experimental NMR, solution and solid-state NMR, overview of electron paramagnetic resonance (EPR) spectroscopy and dynamic nuclear polarization (DNP).

This interdisciplinary course will introduce advanced undergraduates and graduates to molecules and their chemistry in different sources throughout the universe. Topics include gas-phase and grain-surface reactions, astronomical spectroscopy, laboratory experiments, and astrochemical modeling.

Introduces the electronic structure of compounds of the transition metals using ligan field theory and molecular orbital theory. Describes the chemistry of coordination and organometallic compounds, emphasizing structure, reactivity, and synthesis. Examines applications to transformations in organic chemistry and to catalysis. Prerequisite: CHEM 4320 or instructor permission.

Covers mathematical language which describes symmetry and focuses on its application to inorganic chemistry, determination of point groups, use of character tables, and construction of MO theory diagrams. This will be followed by application of these concepts to spectroscopic methods, e.g. Absorption, IR, Raman, NMR, magnetism, and EPR, etc. The material is intended to cover the theory and interpretation of standard spectroscopic techniques.

Covers an introduction to nanomaterials and to physical methods for nanomaterials characterization; synthesis, surface modification and assembly nanomaterials; and magnetic, optical and catalytic properties of nanomaterials. The course also highlights the importance of the design of nanomaterials for modern energy, environmental and biomedical applications.