Applications of analytical techniques to actual problems in industrial regulatory, and instrumentation development laboratory settings. The place of analytical chemistry in related disciplines. The analytical chemical academic-industrial interface. Visiting industrial seminar speakers. Format flexible. Prerequisite: CHEM 513 or 515.

Not available at this time

This course will survey the current picture in pharmaceutical research, including how targets are selected, how the rational and combinatorial methods are harnessed, as well as how the industry is evolving in the post-genomic era. The instructors will provide background and introduce various topics, which will be discussed by a series of invited lecturers who are active in drug design and discovery. Prerequisites: One BIOCHEM class and one year of Organic Chemistry required.

Organic and hybrid semiconductors play an central role in organic electrics. This course will teach students core concepts in the area of organic and hybrid semiconductors. Principles and concepts learned from this course can be translated to advanced problems in materials chemistry.

Organometallics play an important role in synthetic chemistry. This course will teach students core concepts in the area of organometallic chemistry. Principles and concepts learned from this course can be translated to advanced problems in the areas of synthetic chemistry.

Intermolecular interactions play an important role in chemistry. This course will teach students core concepts in the area of supramolecular chemistry. Principles and concepts learned from this course can be translated to advanced problems in the areas of chemistry, materials science and biological sciences.

Not available at this time

Short review of thermodynamics. Introduction to statistical thermodynamics and its application to chemical problems. Statistical mechanical basis of thermodynamic behavior, e.g., entropy and attainment of equilibrium, and derivation of thermodynamic properties from basic microscopic description of molecules and solids, via quantum mechanics. Other topics may include gas imperfections, theory of liquids, adsorption, and molecular simulations.

This course describes how the principles and techniques of organic chemistry, analytical chemistry, and physical chemistry can be used to study proteins, nucleic acids, and sugars. Methods for their synthesis, purification, and chemical manipulations will be discussed, focusing on the application of chemical approaches to studying biological questions. For each topic, appropriate bioanalytical techniques will be emphasized.

This class is focused on computational and mathematical problems in chemistry using modern symbolic computational tools. Using the free desktop software platforms (primarily Mathematica) which are free to UMass students via site license, we will develop tools for data visualization and manipulation, and statistical methods in chemistry, kinetic modeling using analytic and numerical differential equation solving tools and visualization of solutions. In addition, we will explore elements of linear algebra, linear transformations, and group theory as applied to chemical systems.