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Course Criteria
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3.00 Credits
Lecture, 3 hours. Topics include atomic structure, symmetry, and group theory of small molecules and the relationship of these concepts to bonding theory and molecular spectroscopy. Applications of symmetry and group theory to coordination chemistry of transition metal complexes in organometallic, environmental, bioinorganic, and materials chemistry. Other topics include kinetics and mechanisms of inorganic and organometallic reactions including electron transfer.
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5.00 Credits
Lecture, 3 hours; laboratory lecture, 1 hour; laboratory, 3 hours. Basic course in the general theory and reactions of organic chemistry. Emphasis on basic principles. Recommended for science and pre-professional majors. Prerequisite: CHEM 115B or consent of instructor.
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3.00 Credits
Lecture, 3 hours. Continuation of CHEM 335A. Prerequisite: CHEM 335A.
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2.00 Credits
Laboratory lecture, 1 hour; laboratory, 3 hours. Fundamental techniques of organic chemistry, emphasizing synthetic organic chemistry, modern instrumental methods, and qualitative organic analysis. Designed to complement CHEM 335B. Prerequisite: CHEM 335A.
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1.00 - 6.00 Credits
Supervised chemistry work experiences that involve practical application of previously studied theory. Intended for professional growth and/or collection of data for future theoretical interpretation. Not applicable toward the chemistry major or minor. May be repeated for up to a total of 6 units. Two hours of work per week for each unit of credit. Cr/NC only. Prerequisite: junior standing or consent of instructor.
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3.00 Credits
Lecture, 1 hour; laboratory, 6 hours. An integrated inquiry and project-based upper-division course for B.S. and B.A. chemistry majors. Capstone course for B.A. chemistry degree. The projects will cover the synthesis of organic and inorganic molecules and characterization of student-prepared molecules. Lecture will focus on analysis of spectroscopic data, an overview of the instrumental hardware, and principles of chromatography. Topics include basic electronics, optics, signal to noise, detectors, IR, optical, NMR and fluorescence spectroscopy, mass spectrometry, and chromatography. Prerequisites: CHEM 255. Highly recommended: CHEM 336.
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3.00 Credits
Lecture, 1 hour; laboratory, 6 hours. Project-based synthesis, purification, and characterization of inorganic, organic, and organometallic molecules. Capstone course for B.S. chemistry degree. Topics will include air-sensitive syntheses, standard Schlenk line techniques, characterization through IR, optical and NMR spectroscopy, mass spectrometry, and electrochemistry. Prerequisite: CHEM 401. Highly recommended: CHEM 325.
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3.00 Credits
Lecture, 1 hour; laboratory, 6 hours. Project-based laboratory course involving isolation, purification, and characterization of proteins from natural sources. Capstone course for BS biochemistry degree. The course provides an introduction to biochemical methods, instrumentation, and experimental design techniques common in biotechnology and research. Prerequisites: CHEM 445 or BIO 123, and a foundation in spectroscopy, kinetics, and thermodynamics, or consent of instructor. Strongly recommended: CHEM 255.
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3.00 Credits
Lecture, 3 hour. A study of the structure:function relationships of amino acids, proteins and enzymes, carbohydrates, lipids, and nucleic acids. Also includes topics such as enzyme kinetics, membrane transport, and signaling. Prerequisites: CHEM 335B or CHEM 232 and a foundation in spectroscopy, kinetics, and thermodynamics, or consent of instructor.
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3.00 Credits
Lecture, 3 hours. A study of bioenergetics and metabolism of carbohydrates, lipids, and proteins. Includes a brief review of enzyme kinetics. Prerequisites: CHEM 335B or CHEM 232, CHEM 445 or BIOL 123, and a foundation in spectroscopy, kinetics, and thermodynamics, or consent of instructor.
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