The application of chemical principles to modern materials discovery, design, and characterization will be discussed. Topics covered will include inorganic solids, nanoscale materials, polymers, inorganic-organic hybrid materials, and biological materials, with specific focus on how the atomic-level chemistries dictate material properties across various length scales. Aspects of materials chemistry with regard to scalability and sustainability will also be covered.

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.

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.

The Commonwealth Honors College thesis or project is intended to provide students with the opportunity to work closely with faculty members to define and carry out in-depth research or creative endeavors. It provides excellent preparation for students who intend to continue their education through graduate study or begin their professional careers. The student works closely with their 499Y Honors Research sponsor to pursue research on a topic or question of special interest to them in preparation for writing a 499T Honors Thesis or completing a 499P Honors Project.

Honors Thesis expectations are high. The intended end-product is a traditional research manuscript with accompanying artifact(s), all theses: - are 6 credits or more of sustained research on a single topic, typically conducted over two semesters. - begin with creative inquiry and systematic research. - include documentation of substantive scholarly endeavor. - culminate in an oral defense or other form of public presentation.

Honors Project expectations are high. The intended end-product is a traditional project manuscript with accompanying artifact(s), all projects: - are 6 credits or more of sustained research on a single topic, typically conducted over two semesters. - begin with creative inquiry and systematic research. - include documentation of substantive scholarly endeavor. - culminate in an oral defense or other form of public presentation.

This is a stand-alone independent study designed by the student and faculty sponsor that involves frequent interaction between instructor and student. Qualitative and quantitative enrichment must be evident on the proposed contract before consent is given to undertake the study.

For fourth year students. Does not satisfy the B.S. independent research project requirement. Experimental or theoretical study that may involve lab or library work or a combination. Work supervised by faculty sponsor who determines direction of project, nature of reports required, and grade and credit awarded. 3-4 hrs lab work per week per 1 unit is expected. This course cannot substitute for CHEM 388 or CHEM 499Y/T.

Introduction to the laws controlling equilibrium and kinetic properties of macroscopic chemical systems, using thermodynamics and statistical mechanics. Prerequisites: CHEM 475