Detailed treatment of thermodynamics and chemical kinetics. Topics include equations of state, laws of thermodynamics, phase and reaction equilibrium, reaction kinetics, and thermodynamic properties of polymers, solutions, and of biochemical and electrochemical processes. C (2.0) or higher in all prerequisites.

Prerequisites:

MATH 121, PHYS 211, CHEM 305

Detailed treatment of quantum mechanics, spectroscopy, and statistical thermodynamics. Topics include the foundations of quantum mechanics, application of quantum mechanics to atomic and molecular structure, foundations of spectroscopic techniques, photophysics and photochemistry, statistical thermodynamics, and molecular aspects of reaction kinetics. "C" (2.0) or higher in all prerequisites.

Prerequisites:

MATH 122, PHYS 212, CHEM 445

Laboratory to accompany CHEM 445. An advanced treatment of measurement theory and data analysis precedes a series of thermodynamic and kinetic experiments designed to complement topics treated in lecture to help students' independence and sophistication in planning, performing, and reporting experimental work. Prereq: CHEM 445 previously or concurrently

Prerequisites:

CHEM 445

Laboratory to accompany CHEM 446. Experiments and computational projects in quantum mechanics, spectroscopy, and statistical mechanics. The experiments and projects will continue to work toward the goal of increasing the students' independence and sophistication. Prereq: C (2.0) or better in CHEM 445; pre or coreq: CHEM 446

Prerequisites:

CHEM 445

Detailed analysis of the structures, properties, and functions of proteins, carbohydrates, and lipids; introduction to carbohydrate metabolism; theory for the purification and analysis of proteins. Concurrent enrollment in CHEM 465 is recommended.

Prerequisites:

BIOL 106, CHEM 324. BIOL 106 or permission "C" (2.0) or higher in all prerequisites.

Detailed analysis of the reactions involved in intermediary metabolism, translation, transcription, and replication.

Prerequisites:

CHEM 460

A lecture/laboratory course, which presents methodology and instrumentation used to purify and analyze biomolecules. Techniques include chromatography, radioisotope techniques, polyacrylamide gel electrophoresis, spectrophotometry, and PCR analysis.

Prerequisites:

Concurrent registration in CHEM 460 or completion of CHEM 460 with "C" or higher. CHEM 305 is highly recommended.

Students work in teams to solve biochemical research problems by analyzing data from experiments which they design.

This course will focus on the interface of cancer and medicine. Topics will provide a comprehensive overview of the hallmarks of cancers, mechanisms of tumorigenesis and metastasis, while simultaneously emphasizing drug design, mechanisms of action, and structure-activity relationships for targeting these pathways in precision medicine. Past/current treatments will be evaluated for their therapeutic benefits, side effects, and resistance mechanisms. Moreover, primary literature will serve to illustrate the concepts and how these malignancies are modeled in research for drug discovery and development.

Prerequisites:

CHEM 360 or CHEM 460

Theory and practice of modern instrumental methods including basic electronics. Special emphasis placed on sampling methods, analog and digital electronics, electrochemistry, spectrophotometric and chromatographic methods, surface and thin-film analysis and computer acquisition and data processing techniques.

Prerequisites:

CHEM 305. PHYS 212 or PHYS 223.

Methods and materials for teaching physical sciences in middle school through high school. Clinical experiences are required for the course.

Prerequisites:

Consent

In this course, students will develop discipline-specific skills in critical reading and evaluation of the primary and secondary literature, including the use of libraries and databases to identify reliable sources. Work will culminate in a literature review that synthesizes the current state of research in synthetic polymers, biological macromolecules, supramolecular aggregates and/or meso/nanoscale materials with consideration toward future directions. Throughout the course, students will participate in peer review, revision of written work, learn key ethical considerations of writing, develop better writing mechanics and understand different conventions of scientific writing all while increasing their familiarity in the topics above.

Prerequisites:

ENG 101, CHEM 324

Capstone course for majors in Chemistry, Biochemistry, and Chemistry Teaching. During this course, students will present their mentored undergraduate research projects OR present a literature review synthesized from primary literature articles. Forums for presentation include an oral presentation and poster presentation.

Prerequisites:

CHEM 445 or CHEM 465

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This is research mentored by a faculty member in the Department. The Research mentor will work with the student to create a document outlining research goals and time commitment for each credit or registration attempt. In order for CHEM 498 credits to apply to the student's program of study as unrestricted elective credits, the student must submit a formal written report that meets ACS or ASBMB requirements at the end of their research.

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Detailed analysis of the structures, properties, and functions of proteins, carbohydrates, lipids, and nucleic acids; theory for the purification and analysis of proteins and nucleic acids. Concurrent enrollment in CHEM 565 is recommended.

Detailed analysis of the reactions involved in intermediary metabolism, translation, and replication.

A lecture/laboratory course which presents methodology and instrumentation used to purify and analyze biomolecules. Techniques include chromatography, autoradiography and radioisotope techniques, agarose and polyacrylamide gel electrophoresis, and spectrophotometry.

Students work in teams to solve biochemical research problems by conducting and analyzing experiments which they design.

This course will focus on the interface of cancer and medicine. Topics will provide a comprehensive overview of the hallmarks of cancers, mechanisms of tumorigenesis and metastasis, while simultaneously emphasizing drug design, mechanisms of action, and structure-activity relationships for targeting these pathways in precision medicine. Past/current treatments will be evaluated for their therapeutic benefits, side effects, and resistance mechanisms. Moreover, primary literature will serve to illustrate the concepts and how these malignancies are modeled in research for drug discovery and development. Additionally, graduate students will evaluate a novel/biography of cancer to assess the history of cancer research.

Methods and materials for teaching physical sciences in middle school through high school. Clinical experiences required for the course.

Beginning Mandarin I is a practical introductory language course with simple, graded activities on essential daily topics. Students will begin to work orally and with the Chinese writing systems, while developing early listening and reading skills.

Beginning Mandarin II is a practical introductory language course with simple, graded activities on essential daily topics. Students will continue to work orally and with the Chinese writing systems, while developing early listening and reading skills.