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.

Covers physical methods for characterizing structure, composition, & surface chemistry of inorganic nanomaterials. Methods discussed include electron & probe microscopies, X-ray techniques, vibrational spectroscopies, & UV-visible spectroscopy. We will explore the use of these & other techniques across ex situ, in situ, & operando conditions for the determination of structure-function relationships & reaction mechanisms.

Introduces the components of biological macromolecules and the principles behind their observed structures. Examines the means by which enzymes catalyze transformations of other molecules, emphasizing the chemical principles involved, and describes key metabolic cycles and pathways, the enzymes that catalyze these reactions, and the ways in which these pathways are regulated. Three class hours (Y) Prerequisites: One year of biochemistry; one year of organic chemistry; one semester of thermodyanmics.

Focuses on the development of skills in methods of preparation, purification and identification of organic compounds. This course is designed for students who are pre-health students and NOT chemistry majors/minors.Prerequisite: CHEM 1421, 1621, or 1811. CHEM 2410 or 1820 must be taken concurrently or prior to CHEM 2311. Drop/withdrawal from CHEM 2410/1820, requires drop/withdrawal from CHEM 2311.

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.

Topics include principles of image formation; methods for sample preparation and chemical labeling; photophysics of fluorescent proteins and organic dyes; and computational image analysis and data processing.Recommended prerequisites: Calculus II or higher, Introduction to Biology. Required prerequisites: CHEM 1420, 1620 or 1810.

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).

An introduction to classic & modern approaches of chemical analysis of biological systems. Detection of analytes ranging from small molecules & proteins, to cells, to structured materials. Focus on immunoassays: ELISA, bead-based assays, & surface plasmon resonance for analytes in solution; ELISpot for cell secretions; flow cytometry for cells and beads; & immunostaining for biomaterials and tissue samples. Prerequisite: CHEM 4410

Execution of laboratory experiments that illustrate important laws and demonstrate quantitative methods of measuring the chemical and physical properties of matter. One hour lab lecture and four hour laboratory meet weekly. Prerequisite: CHEM 3811. CHEM 3420 must be taken concurrently or prior to CHEM 3821. Drop/withdrawal from CHEM 3420, requires drop/withdrawal from CHEM 3821.

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.