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Professors
Steven R. Angle, Ph.D.
Guy Bertrand, Ph.D.
David F. Bocian, Ph.D.
Eric L. Chronister, Ph.D.
Robert Haddon, Ph.D. (Chemistry/Chemical and Environmental Engineering)
Werner G. Kuhr, Ph.D.
M. Mark Midland, Ph.D.
Thomas H. Morton, Ph.D.
William H. Okamura, Ph.D.
Dallas L. Rabenstein, Ph.D.
Christopher A. Reed, Ph.D.
Michael F. Rettig, Ph.D.
Gary W. Scott, Ph.D.
Christopher Y. Switzer, Ph.D.
Francisco Zaera, Ph.D.
Professors Emeriti
Walter J. Deal, Ph.D.
Everly B. Fleischer, Ph.D.
Harry W. Johnson, Jr., Ph.D.
George K. Helmkamp, Ph.D.
Robert C. Neuman, Jr., Ph.D.
William H. Orttung, Ph.D.
James N. Pitts, Jr., Ph.D.
Donald T. Sawyer, Ph.D.
Hartland H. Schmidt, Ph.D.
Charles L. Wilkins, Ph.D.
Richard M. Wing, Ph.D.
Assistant Professors
Ludwig Bartels, Ph.D.
Quan Cheng, Ph.D.
Pingyun Feng, Ph.D.
T. Keith Hollis, Ph.D.
Sheri J. Lillard, Ph.D.
Michael J. Marsella, Ph.D.
Leonard J. Mueller, Ph.D.
Yinsheng Wang, Ph.D.
Jingsong Zhang, Ph.D.
••
Cooperating Faculty
Roger Atkinson, Ph.D.
Jocelyn G. Millar, Ph.D.
Paul J. Ziemann, Ph.D.

MAJOR

The Department of Chemistry offers a B.A. and B.S. degree in Chemistry and a B.S. in Chemistry with a Chemical Physics option or an Environmental Chemistry option.

Bachelor of Arts Degree The B.A. program is designed for students who wish to obtain a broad educational background with less intensive emphasis on chemistry. In this program, students have increased ease in meeting requirements for such areas as premedical, predental, or prepharmaceutical science; education; and administration.

Bachelor of Science Degree The B.S. program is certified by the American Chemical Society and is designed for students interested in a professionally oriented major leading most often to a career or advanced study in chemistry.

A chemical physics option is available for students who wish to prepare for admission to a graduate program in chemical physics.

The environmental chemistry option is available for students who wish to become familiar with environmental processes and problems related to air, water, and soil, and to apply their chemical knowledge working in environmental-related areas. This option also prepares students for admission to a graduate program emphasizing environmental chemistry.

Pre-Health Science Chemistry majors in either the B.A. or B.S. programs can prepare for admission to medical, pharmacy, or dental schools by carefully planning their programs of study. Students planning to apply for post-graduate studies in the health sciences should make it a special point to consult with the Chemistry undergraduate advisor early in their studies at UCR.

Teaching Credential

Teachers in the public schools in California must have a credential approved by the State Commission on Teacher Credentialing. The credential requires an undergraduate major, baccalaureate degree, and completion of a graduate credential program such as that offered by the Graduate School of Education at UCR. The latter usually requires three quarters and includes education courses and supervised teaching.

Before admission and student teaching in a graduate credential program, the candidate must pass the California Basic Education Skills Test (CBEST) and demonstrate subject-matter proficiency in the fields in which the candidate will teach. The candidate can demonstrate proficiency either by passing the commission's subject-matter assessment examination, or preferably, by completing an undergraduate program that is state-approved for teacher preparation.

UCR has an approved undergraduate program for Chemistry majors who plan to get a Multiple Subjects Credential and teach in the elementary (K-6) grades. A breadth of course work is necessary, in addition to the specified requirements for the major. Students are urged to start early, preferably as freshmen, selecting courses most helpful for this career. Details and counseling on the Bridge to Teaching Program, a waiver program for the multiple subjects credential, are available in the Liberal Arts and Interdisciplinary Programs office, (909) 787-2743. Details and counseling on other waiver programs are available in the Department of Chemistry or the Graduate School of Education.

UCR does not yet have a state-approved undergraduate program for chemistry majors who wish to teach at the secondary level. The Teaching Credential in Science, chemistry emphasis, is required for chemistry teachers, grades 7-12. Students who plan to get this credential must take the commission's subject-matter assessment examination and should make certain their academic program includes preparatory course work. The examination includes chemistry in depth and general science with introductory, college-level biology, chemistry, physics, and geoscience (geology, meteorology, oceanography, astronomy).

Further information about courses, requirements, and examinations can be obtained in orientation meetings, the Student Affairs Office (1221 Pierce Hall), and the Graduate School of Education (1215 Sproul Hall).

Career Opportunities

Most present-day chemists work in industrial firms, government, and education. Although many chemists eventually leave the research laboratory for positions in management, marketing, or production, the most common professional assignments are in research and development. Chemists are involved in the development, production, testing, control, and sales of products such as medicines, glasses, metals, agrochemicals, paints, rubber, plastics, soaps and detergents, and plant nutrients. An increasing number of chemists are involved in the fields of molecular biology, air and water quality, and the development of new sources of energy and new high-technology materials.

The federal government and nonprofit foundations also employ chemists. Such agencies as the National Institutes of Health, Department of Energy, the Environmental Protection Agency, National Aeronautics and Space Administration, National Institutes of Science and Technology, and Food and Drug Administration require scientific and technological advice and administration as well as chemical research.

The bachelor's degree programs in the Department of Chemistry are well suited for preparation for general, technical, professional, and health-science careers. After graduation, UCR students may be professionally employed; go on to graduate work; or enter business, medical, or other professional schools.

Transfer Students

1. General chemistry, equivalent to CHEM 001A-CHEM 001B-CHEM 001C, each course completed with a grade of "C" or better
2. First-year calculus, equivalent to MATH 009A-MATH 009B-MATH 009C, each course completed with a grade of "C" or better

At least one of the following one-year sequences:

1. Second-year calculus, equivalent to MATH 010A, MATH 010B, MATH 046, each course completed with a grade of "C" or better
2. General physics (calculus-based) equivalent to PHYS 040A, PHYS 040B, PHYS 040C, each course completed with a grade of "C" or better
3. Organic chemistry (one-year lower-division), each course completed with a grade of "B" or better

Students must have a minimum grade point average of 2.70 in transferable college courses.

Degree Requirements

University Requirements

College Requirements

Some of the following requirements for the major may also fulfill some of the college's breadth requirements. Consult with a department advisor for course planning.

Major Requirements

The major requirements for the B.A. and the B.S. degree in Chemistry are as follows:

Bachelor of Arts

1.  Lower-division requirements (48-49 units)

a)  MATH 009A-MATH 009B-MATH 009C, MATH 010A
b)  PHYS 040A, PHYS 040B, PHYS 040C (or PHYS 002A, PHYS 02LA, PHYS 002B, PHYS 02LB, PHYS 002C, PHYS 02LC)
c)  CHEM 001A-CHEM 001B-CHEM 001C (or CHEM 01HA, CHEM 01HB, CHEM 01HC), CHEM 005

2.  Upper-division requirements (38 units)A minimum grade of "C-" for any upper-division course used to fulfill the requirements for the B.A. degree.

a)  CHEM 110A, CHEM 110B, CHEM 112A-CHEM 112B-CHEM 112C, CHEM 113, CHEM 125, CHEM 150A, CHEM 191, and either CHEM 111 or CHEM 166
b)  Ten (10) additional upper-division units in Chemistry if the year of organic chemistry is taken at a community college

Bachelor of Science

1.  Lower-division requirements (61-62 units)

a)  CHEM 001A-CHEM 001B-CHEM 001C (or CHEM 01HA, CHEM 01HB, CHEM 01HC), CHEM 005
b)  MATH 009A-MATH 009B-MATH 009C, MATH 010A, MATH 010B, MATH 046
c)  PHYS 040A, PHYS 040B, PHYS 040C, PHYS 040D

2.  Upper-division requirements (50 units)A minimum grade of "C-" for any upper-division course used to fulfill the requirements for the B.S. degree.

a)  CHEM 110A, CHEM 110B, CHEM 111, CHEM 112A-CHEM 112B-CHEM 112C, CHEM 113, CHEM 125, CHEM 150A, CHEM 191
b)  Two laboratory courses from the group CHEM 140, CHEM 166, BCH 102
c)  One course from the group CHEM 150B, CHEM 135/ENSC 135/ENTX 135, CHEM 136/ENSC 136/ENTX 136/SWSC 136, BCH 110A

Chemical Physics Option

Students must consult with the undergraduate advisor before electing this option.

1.  Lower-division requirements (61-62 units)

a)  CHEM 001A-CHEM 001B-CHEM 001C (or CHEM 01HA, CHEM 01HB, CHEM 01HC), CHEM 005
b)  MATH 009A-MATH 009B-MATH 009C, MATH 010A, MATH 010B, MATH 046
c)  PHYS 040A, PHYS 040B, PHYS 040C, PHYS 040D

2.  Upper-division requirements (74 units)A minimum grade of "C-" for any upper-division course used to fulfill the requirements for the Chemical Physics option.

a)  CHEM 110A, CHEM 110B, CHEM 111, CHEM 112A-CHEM 112B-CHEM 112C, CHEM 113, CHEM 140, CHEM 150A, CHEM 150B, CHEM 191
b)  Twenty-four (24) units of upper-division course work in Mathematics or Physics (110 or above excluding 190 series)
c)  Nine (9) additional units in physical chemistry

Environmental Chemistry Option

Students must consult with the undergraduate advisor before electing this option.

1.  Lower-division requirements (73-74 units)

a)  CHEM 001A-CHEM 001B-CHEM 001C (or CHEM 01HA, CHEM 01HB, CHEM 01HC), CHEM 005
b)  MATH 009A-MATH 009B-MATH 009C, MATH 010A, MATH 010B, MATH 046
c)  PHYS 040A, PHYS 040B, PHYS 040C, PHYS 040D
d)  BIOL 005A, BIOL 005B, BIOL 005C

2.  Upper-division requirements (64-68 units)A minimum grade of "C-" for any upper-division course used to fulfill the requirements for the Environmental Chemistry option.

a)  CHEM 110A, CHEM 110B, CHEM 111, CHEM 112A-CHEM 112B-CHEM 112C, CHEM 113, CHEM 125, CHEM 135/ENSC 135/ENTX 135, CHEM 136/ENSC 136/ENTX 136/SWSC 136, CHEM 140, CHEM 150A, CHEM 166, CHEM 191
b)  One course from ENSC 104/SWSC 104 or GEO 137
c)  Two additional courses from the group CHEM 150B, CHEM 197, CHEM 199, ENSC 104/SWSC 104, ENSC 140/SWSC 140, ENSC 142, ENSC 155, ENSC 163, ENTX 101, GEO 137, GEO 160 (4 units total from CHEM 197 and/or CHEM 199)

Undergraduate research is strongly encouraged for students with the requisite ability. Students wishing to participate in this activity should contact individual faculty members concerning areas of interest.

Sample Program

Student programs are planned on an individual basis with their advisors, and there is considerable flexibility in the sequence in which courses required for the major are taken. For example, PHYS 040A, PHYS 040B, PHYS 040C can be started equally well during either the freshman or sophomore year. The sample program is typical for a well-prepared entering freshman who seeks the B.S. degree.

Minor

The minor in Chemistry consists of 28 upper-division units in chemistry.

1. No more than 8 of the 28 upper-division units may be in courses required in the student's major.
2. At least one of the courses used to satisfy the 28 units must be in CHEM 125, CHEM 111, CHEM 140 or CHEM 166 (courses which include laboratory work).

All of the upper-division courses in chemistry have a prerequisite of CHEM 001A-CHEM 001B-CHEM 001C or CHEM 01HA, CHEM 01HB, CHEM 01HC and most have CHEM 005 as a prerequisite.

Students with a minor in Chemistry should consult with the Chemistry undergraduate advisor to construct a specific program consistent with their career goals.

See Minors under the College of Natural and Agricultural Sciences in the Undergraduate Studies section of this catalog for additional information on minors.

GRADUATE PROGRAM

Fields of specialization (subdisciplines) offered by the Department of Chemistry are analytical chemistry, inorganic chemistry, organic chemistry, and physical chemistry. Research is also carried out in bioanalytical, bioinorganic, bioorganic, and biophysical chemistry and in chemical physics, environmental/atmospheric, organometallic chemistry, and neuroscience. For additional information on the latter, please see Neuroscience Graduate Program in the Curricula and Courses section of this catalog. All applicants are required to submit scores from the GRE General Test. A score from the Advanced Chemistry GRE is not required for admission. It is strongly recommended, however, that applicants submit this score in order to receive maximum consideration for fellowships. The department normally considers applications for teaching and research assistantships at the same time as fellowships; therefore, students are strongly encouraged to complete their applications for admission and support as early as possible. Normally applications for fellowships are awarded by February for students entering in the following fall quarter. Although most students begin in the fall quarter, students may begin their studies in the winter or spring quarter.

Orientation Examinations

Master's Degree

Requirements are: 

1. Satisfactory performance in orientation examinations in analytical, inorganic, organic, and physical chemistry
2. General University requirements; and departmental requirements for either Plan I or Plan II.

Plan I (Thesis)

a) At least 36 units of approved courses and graduate research of which five regular lecture courses in the CHEM 200-249 series (CHEM 110A or CHEM 110B, CHEM 113, CHEM 125, and CHEM 150A or CHEM 150B may apply under certain circumstances) must be included. A maximum of 12 units of seminar courses (CHEM 250-259) and a maximum of 12 units of graduate research; (but not those numbered CHEM 260-289) may apply towards the 36 units.
b) A thesis
c) A final oral examination on the thesis may be required.

Plan II (Comprehensive Examination)

a) At least 36 units of approved courses of which at least 18 must be in regular lecture courses numbered CHEM 200-249 (CHEM 110A or CHEM 110B, CHEM 113, CHEM 125, and CHEM 150A or CHEM 150B may apply under certain circumstances) and up to 12 units of graduate seminar courses numbered CHEM 250-259. Those numbered CHEM 260-289 are specifically excluded.
b) Passing at least two cumulative examinations

Doctoral Degree

The requirements are orientation examinations in analytical, inorganic, organic, and physical chemistry; general university requirements; and departmental requirements.

Program of Study A program of study will be required by the departmental committee on graduate study on the basis of the students' performance on the orientation examinations and a consideration of their subdisciplines. For students with a normal B.S. level preparation, the typical course pattern for each subdiscipline is as follows: analytical (a minimum of three courses selected from CHEM 221A-CHEM 221B-CHEM 221C-CHEM 221D-CHEM 221E plus two other courses), inorganic (CHEM 231A, CHEM 231B, CHEM 231C plus two other courses); organic (CHEM 211A-CHEM 211B-CHEM 211C plus two other courses) and physical (a minimum of three courses selected from CHEM 201A-CHEM 201B-CHEM 201C-CHEM 201D-CHEM 201E plus two other courses).

Cumulative Examinations To encourage a planned program of study and literature reading carried out concurrently with research, the major written examinations in each subdiscipline offered for the doctor's degree (namely, analytical, inorganic, organic and physical chemistry) shall consist of cumulative examinations. Nine examinations are given each year, the first in September and the last in June. Students may begin the cumulative examinations at any time during their first year in residence. Once the examination program has been started, students may elect to take the examinations sequentially or skip selected examinations at their discretion. However, no student is given more than the 15 attempts to pass the six examinations needed to satisfy the requirement. In addition, the six examinations must be passed before the end of the second year in residence.

Foreign Language A reading knowledge of German, French, or Russian is recommended but not required for the doctoral degree in chemistry.

Oral Qualifying Examination After passing the required number of cumulative examinations, the candidates are given an oral examination by their doctoral committee. This examination consists in part of defending an original proposition and is designed to test the extent of the candidates' development and their breadth of knowledge in chemistry and related fields.

Teaching Assistant Experience Three quarters of service as a teaching assistant, or equivalent, are normally required.

Normative Time to Degree 15 quarters

Lecture, three hours; laboratory, three hours. Prerequisite(s): for CHEM 001A: CHEM 001W or MATH 005 or a grade of "C" or better in an equivalent course or a passing score on the Chemistry Placement Examination; for CHEM 001B: a grade of "C-" or better in CHEM 001A; for CHEM 001C: a grade of "C-" or better in CHEM 001B. An introduction to the basic principles of chemistry. Credit is awarded for only one of CHEM 001A or CHEM 01HA, only one of CHEM 001B or CHEM 01HB, and only one of CHEM 001C or CHEM 01HC.

CHEM 01HA. Honors General Chemistry. (4)

Lecture, three hours; laboratory, three hours. Prerequisite(s): concurrent enrollment in or completion of MATH 009A or MATH 09HA or equivalent, a score of at least 640 on the quantitative SAT test, high school chemistry; or consent of instructor. Honors course corresponding to CHEM 001A. A limited enrollment course in which the principles of chemistry are covered in more depth than in CHEM 001A. Credit is awarded for only one of CHEM 001A or CHEM 01HA.

CHEM 01HB. Honors General Chemistry. (4)

Lecture, three hours; laboratory, three hours. Prerequisite(s): CHEM 001A with a grade of "B" or better or CHEM 01HA with a grade of "B" or better or consent of instructor. Honors course corresponding to CHEM 001B. A limited enrollment course in which the principles of chemistry are covered in more depth than in CHEM 001B. Credit is awarded for only one of CHEM 001B or CHEM 01HB.

CHEM 01HC. Honors General Chemistry. (5)

Lecture, three hours; laboratory, six hours. Prerequisite(s): CHEM 001B with a grade of "B" or better or CHEM 01HB with a grade of "B" or better or consent of instructor. Honors course corresponding to CHEM 001C. A limited enrollment course in which the principles of chemistry are covered in more depth than in CHEM 001C. Credit is awarded for only one of CHEM 001C or CHEM 01HC.

CHEM 001W. Preparation for General Chemistry. (3) F

Workshop, three hours. Prerequisite(s): concurrent enrollment in or completion of MATH 003 or MATH 005. For students who are not prepared or qualified for admission to CHEM 001A. Instruction and practice in concept manipulation and problem solving to prepare students to master material in CHEM 001A. Concurrent enrollment in CHEM 001A is not allowed. Not open to students who have completed CHEM 001A with a grade of "C-" or better. Counts toward the 180-unit graduation requirement for the baccalaureate degree but does not satisfy any major or college breadth requirements.

CHEM 003. Concepts of Chemistry. (4)

Lecture, three hours; discussion, one hour. Prerequisite(s): none. A survey of basic concepts of Chemistry. Designed for non-science majors and not as preparation for CHEM 001A or CHEM 01HA. Not open to students with credit for CHEM 001A or CHEM 01HA, but students who have completed CHEM 003 may take CHEM 001A or CHEM 01HA for full credit.

CHEM 005. Quantitative Analysis. (5) F,Summer

Lecture, three hours; laboratory, eight hours (two four-hour periods). Prerequisite(s): CHEM 001C or CHEM 01HC with a grade of "C-" or better. Stoichiometric calculations and applications of principles of chemical equilibrium to analytical problems. Titrimetric and gravimetric laboratory procedures.

CHEM 091. Freshman Seminar: What Chemists Do. (1)

Seminar, one hour. Explores the frontiers of chemistry (analytical, inorganic, organic, and physical) as well as the role of chemistry in allied areas such as agriculture, biology, environmental science, forensics, materials, medicine, and neuroscience. Graded Satisfactory (S) or No Credit (NC).

CHEM 097H. Freshman Honors Project: Introduction to Research. (1-4)

Outside research, three to twelve hours. Prerequisite(s): admission to the University Honors Program. Prior arrangement with a chemistry faculty member is required. An introduction to the methods of research in chemical sciences. The student conducts an investigation under the supervision of a faculty member. A written report is required at the end of the quarter. To satisfy the requirement for the University Honors Program Freshman Project, the student must earn a minimum of 4 units during the first year. Satisfactory (S) or No Credit (NC) grading is not available. Course is repeatable.

Lecture, three hours; discussion, one hour. Prerequisite(s): CHEM 001C or CHEM 01HC with a grade of "C-" or better; MATH 009B with a grade of "C-" or better. Thermodynamics, chemical equilibrium, kinetics, quantum chemistry, atomic and molecular structure, and spectroscopy. Primarily for students with major interests in life and agricultural sciences; not recommended for chemistry majors. Not open to students with credit in CHEM 110A, CHEM 110B, and CHEM 113.

CHEM 110A. Physical Chemistry: Chemical Thermodynamics. (4) F

Lecture, three hours; discussion, one hour. Prerequisite(s): MATH 010A with a grade of "C-" or better (or MATH 009C with a grade of "C-" or better if MATH 010A is taken concurrently), and either PHYS 002A, PHYS 002B, and PHYS 002C with grades of "C-" or better or PHYS 040A, PHYS 040B, and PHYS 040C with grades of "C-" or better (PHYS 040C may be taken concurrently); or consent of instructor. Introduction to thermodynamics with applications to chemical systems.

CHEM 110B. Physical Chemistry: Introduction to Statistical Mechanics and Kinetics. (4) W

Lecture, three hours; discussion, one hour. Prerequisite(s): CHEM 110A with a grade of "C-" or better or consent of instructor; prior or concurrent enrollment in MATH 010B is recommended. Statistical mechanics, kinetic molecular theory, and chemical kinetics with applications to chemical systems.

CHEM 111. Physical Chemistry Laboratory. (4) W

Lecture, two hours; laboratory, eight hours. Prerequisite(s): CHEM 110A and CHEM 110B with grades of "C-" or better (CHEM 110B may be taken concurrently), or consent of instructor. CHEM 113 recommended. Physical chemical measurements and laboratory experiments illustrating fundamental principles of physical chemistry. Modern electronic and optical measurement techniques.

CHEM 112A-CHEM 112B-CHEM 112C. Organic Chemistry. (4-4-4) 112A: F,W,Summer; 112B: W,S,Summer; 112C: F,S,Summer

Lecture, three hours; laboratory, four hours. Prerequisite(s): CHEM 001C or CHEM 01HC with a grade of "C-" or better; for CHEM 112B: a grade of "C-" or better in CHEM 112A; for CHEM 112C: a grade of "C-" or better in CHEM 112B. Modern organic chemistry including structure, nomenclature, reactivity, synthesis, and reaction mechanisms and the chemistry of carbohydrates, lipids, nucleic acids, amino acids, and proteins. Laboratory techniques of purification, isolation, synthesis, reactions, and spectroscopic analysis.

CHEM 113. Physical Chemistry: Introduction to Quantum Chemistry. (4) S

Lecture, three hours; discussion, one hour. Prerequisite(s): CHEM 001C with a grade of "C-" or better or CHEM 01HC with a grade of "C-" or better; MATH 009C with a grade of "C-" or better; MATH 046 with a grade of "C-" or better. Introduction to quantum mechanics with application to atomic and molecular structure and spectra.

CHEM 125. Instrumental Methods. (3/5) W

Lecture, three hours; laboratory, eight hours. Prerequisite(s): CHEM 005 with a grade of "C-" or better; either PHYS 02A, PHYS 002B, and PHYS 002C or PHYS 040A, PHYS 040B, and PHYS 040C (PHYS 040C may be taken concurrently) or equivalents or consent of instructor. Chromatographic separations, electrochemistry, and principles of spectroscopic techniques are presented as an introduction to instrumental methods and their use in chemistry. Graduate students may register for either lecture only (3 units) or for lecture and laboratory (5 units).

CHEM 135. Chemistry of the Clean and Polluted Atmosphere. (4) W

Lecture, three hours; discussion, one hour. Prerequisite(s): CHEM 112A-CHEM 112B or consent of instructor; ENSC 102 recommended. Structure of the troposphere and stratosphere; formation of atmospheric ozone; tropospheric NOx chemistry; methane oxidation cycle; phase distributions of chemicals; wet and dry deposition; chemistry of volatile organic compounds; formation of photochemical air pollution; modeling of air pollution and control strategies; stratospheric ozone depletion and global warming. Cross-listed with ENSC 135 and ENTX 135.

CHEM 136. Chemistry of Natural Waters. (4) S

Lecture, three hours; discussion, one hour. Prerequisite(s): CHEM 005 with a grade of "C-" or better or ENSC 104/SWSC 104 with a grade of "C-" or better or consent of instructor. Introduction to processes controlling the chemical composition of natural waters. Topics include chemical equilibria, acid-base and coordination chemistry, oxidation-reduction reactions, precipitation-dissolution, air-water exchange, and use of equilibrium and kinetic models for describing marine nutrient, trace metal, and sediment chemistry. Cross-listed with ENSC 136, ENTX 136, and SWSC 136.

CHEM 140. Environmental Chemistry Laboratory. (4) S

Lecture, two hours; laboratory, eight hours. Prerequisite(s): CHEM 125 with a grade of "C-" or better, CHEM 110A (or CHEM 109) with a grade of "C-" or better; or consent of instructor. Theory and application of chemical techniques for the analysis of environmentally relevant chemical processes. Discusses gas phase, condensed phase, surface, and particulate chemistry. Topics include "acid rain," photochemical smog, ozone depletion, and chemical analysis monitoring.

CHEM 150A. Inorganic Chemistry. (4) W

Lecture, three hours; discussion, one hour. Prerequisite(s): CHEM 112A-CHEM 112B-CHEM 112C with grades of "C-" or better; CHEM 110A (or CHEM 109) with a grade of "C-" or better. A systematic introduction to the synthesis, reactions, structure, and bonding of important classes of inorganic compounds. Emphasis on non-transition metal chemistry.

CHEM 150B. Inorganic Chemistry. (4) S

Lecture, three hours; discussion, one hour. Prerequisite(s): CHEM 150A with a grade of "C-" or better. A systematic introduction to synthesis, reactions, structure, and bonding of important classes of inorganic compounds. Emphasis on transition metal chemistry.

CHEM 166. Advanced Structural and Synthetic Methods. (2-4) S

Lecture, two hours; laboratory, eight hours. Prerequisite(s): CHEM 112C with a grade of "C-" or better; CHEM 125 and CHEM 150A recommended. Methods for the characterization of organic and inorganic compounds. Advanced methods of synthesis of organic and inorganic compounds such as vacuum, inert atmosphere, high-pressure, and photochemical techniques. Hands-on use of spectroscopic (nuclear magnetic resonance and optical spectroscopy and mass spectrometry) and computer-based methods for structural characterization. Non-chemistry majors and graduate students may register for lecture (2 units) or for lecture and laboratory (4 units).

CHEM 190. Special Studies. (1-5)

To be taken with the consent of the chair of the department as a means of meeting special curricular problems.

CHEM 191. Seminar in Chemistry Careers. (1) S

Seminar, one hour. Prerequisite(s): upper-division standing. Oral reports and discussions by students, faculty, and visiting speakers. Required of chemistry majors; normally taken in the spring of the junior year. Graded Satisfactory (S) or No Credit (NC).

CHEM 197. Research for Undergraduates. (1-4)

Outside research, three to twelve hours. Prerequisite(s): sophomore or junior standing; consent of instructor. An introduction to the methods of research in chemistry. Includes a research project completed under the supervision of a Chemistry faculty member. Students who submit a written research report receive a letter grade; other students receive a Satisfactory (S) or No Credit (NC) grade. Course is repeatable to a maximum of 6 units.

CHEM 198-I. Individual Internship. (1-4)

Internship, three to twelve hours; term paper or preparation for presentation, one to four hours. Prerequisite(s): upper-division standing in chemistry; consent of instructor. Industrial work experience coordinated and supervised by a chemistry faculty member and an off-campus sponsor. A term paper or presentation is required. Course is repeatable to a maximum of 8 units.

CHEM 199. Senior Research. (1-4)

Outside research, three to twelve hours. Prerequisite(s): senior standing; consent of instructor. Research project completed under the supervision of a Chemistry faculty member. Students who submit a written research report receive a letter grade; other students receive a Satisfactory (S) or No Credit (NC) grade. Total credit for CHEM 199 and/or CHEM 199H may not exceed 9 units.

CHEM 199H. Senior Honors Research. (1-5)

Outside research, three to fifteen hours. Prerequisite(s): senior standing; consent of instructor; a minimum GPA of 3.00 in chemistry courses and in all university course work. Research in chemistry conducted under the supervision of a Chemistry faculty member. Students who submit a written research report receive a letter grade; other students receive a Satisfactory (S) or No Credit (NC) grade. Total credit for CHEM 199 and/or CHEM 199H may not exceed 9 units.

Lecture, three hours. Prerequisite(s): for CHEM 201A-CHEM 201B: a grade of C or better in CHEM 113; for CHEM 201C-CHEM 201D-CHEM 201E: CHEM 110A, CHEM 110B. Selected topics in modern physical chemistry, including quantum mechanics, spectroscopy, elementary statistical mechanics, thermodynamics, and chemical kinetics.

CHEM 204. Intermediate Molecular Spectroscopy. (3)

Lecture, three hours. Prerequisite(s): CHEM 113 or equivalent. Spectroscopic applications of basic quantum chemistry, including selected topics from electronic spectroscopy of atoms and molecules; vibrational, rotational, and Raman spectroscopy; coherent and multiphoton laser spectroscopies; and time-domain spectroscopies.

CHEM 205. Chemical Quantum Mechanics. (3)

Lecture, three hours. Prerequisite(s): consent of instructor. The elements of quantum mechanics with particular emphasis on chemical problems.

CHEM 206. Chemical Statistical Mechanics. (3)

Lecture, three hours. Prerequisite(s): consent of instructor. The fundamentals of statistical mechanics and selected topics of current physical-chemical interest.

CHEM 207. Chemical Group Theory. (3)

Lecture, three hours. Prerequisite(s): consent of instructor. The principles of group theory and molecular symmetry. Applications in several areas of chemistry.

CHEM 209 (E-Z). Advanced Topics in Physical Chemistry. (2-3)

Lecture, two hours (2 units) or three hours (3 units). Prerequisite(s): consent of instructor. Additional prerequisites are required for some segments of this course; see Department. Selected advanced topics from modern physical chemistry.

CHEM 211A-CHEM 211B-CHEM 211C. Advanced Organic Chemistry. (3-3-3)

Lecture, three hours. Prerequisites: CHEM 113, CHEM 112C. Structural, mechanistic, and synthetic organic chemistry with intensive emphasis on more advanced aspects of the field.

CHEM 215A-CHEM 215B. Organic Synthesis. (3-3)

Lecture, three hours. Prerequisite(s): CHEM 211A-CHEM 211B-CHEM 211C. An advanced treatment of synthetic organic chemistry. CHEM 215A is not a prerequisite to CHEM 215B.

CHEM 216A-CHEM 216B. Physical Organic Chemistry. (3-3)

Lecture, three hours. Prerequisite(s): CHEM 211A-CHEM 211B-CHEM 211C. An advanced treatment of physical organic chemistry.

CHEM 219 (E-Z). Advanced Topics in Organic Chemistry. (2-3)

Lecture, two hours (2 units) or three hours (3 units). Prerequisite(s): consent of instructor. Selected advanced topics from modern organic chemistry. The contents of these courses will vary. Course may be repeated with different topic (and different letter).

CHEM 221A-CHEM 221B-CHEM 221C-CHEM 221D-CHEM 221E. Advanced Analytical Chemistry. (3-3-3-3-3) F,W,S

Lecture, three hours. Prerequisite(s): CHEM 125. Topics include CHEM-221A: Separation Science; CHEM 221B: Optical Spectroscopy; CHEM 221C: Chemical Instrumentation; CHEM 221D: Electrochemistry; CHEM 221E: Nuclear Magnetic Resonance and Mass Spectroscopy.

CHEM 229 (E-Z). Advanced Topics in Analytical Chemistry. (2-3)

Lecture, two hours (2 units) or three hours (3 units). Prerequisite(s): consent of instructor. Selected advanced topics from modern analytical chemistry. The contents of these courses will vary. Course may be repeated with different topic (and different letter).

CHEM 231A. Structure and Bonding in Inorganic Chemistry. (3)

Lecture, three hours. Prerequisite(s): CHEM 150A, CHEM 150B. Covers advanced synthesis, structure, and bonding in inorganic, coordination, and organometallic chemistry.

CHEM 231B. Reactivity and Mechanism in Inorganic and Organometallic Chemistry. (3)

Lecture, three hours. Prerequisite(s): CHEM 231A. Covers advanced synthesis, reactivity, and mechanism in inorganic, coordination, and organometallic chemistry.

CHEM 231C. Solid State and Materials Inorganic Chemistry. (3)

Lecture, three hours. Prerequisite(s): CHEM 231A. Covers the advanced synthesis, structure, bonding, and properties of inorganic materials.

CHEM 234. Bioinorganic and Metalloprotein Chemistry. (3)

Lecture, three hours. Prerequisite(s): CHEM 231A. Covers the advanced chemistry of metals in biology and model compounds.

CHEM 235. Main Group Chemistry. (3)

Lecture, three hours. Prerequisite(s): CHEM 231A. Covers the synthesis, structure, reactivity, and mechanism in main group chemistry and their relationships to organic chemistry.

CHEM 236. Physical Methods in Inorganic Chemistry. (3)

Lecture, three hours. Prerequisite(s): CHEM 231A. Surveys physical methods applied to inorganic chemistry including X-ray structure, infrared (IR), nuclear magnetic resonance (NMR), mass spectroscopy, electron paramagnetic resonance (EPR), Mössbauer, magnetic susceptibility, and theory.

CHEM 239 (E-Z). Advanced Topics in Inorganic Chemistry. (2-3)

Lecture, two hours (2 units) or three hours (3 units). Prerequisite(s): graduate standing. Prerequisites are required for some segments of this course; see department. Covers selected advanced topics in modern inorganic chemistry. The contents of the segments vary.

CHEM 241. Bioorganic Chemistry. (3)

Lecture, three hours. Prerequisite(s): BCH 100 or BCH 110A; BCH 184 or CHEM 110B; CHEM 112A-CHEM 112B-CHEM 112C; graduate standing or consent of instructor. Biochemical reactions discussed from a chemical standpoint, including reactions associated with bioenergetics, biosynthesis, and enzyme catalysis. Emphasis on reaction mechanisms. Cross-listed with BCH 241.

CHEM 244. Airborne Toxic Chemicals. (3)

Lecture, three hours. Prerequisite(s): CHEM 109 or CHEM 110A; and CHEM 110B, CHEM 135/ENSC 135/ENTX 135; or consent of instructor. Atmospheric chemistry of airborne chemicals. Intermedia partitioning. Structure of the atmosphere. Gas-particle distributions of chemicals, and wet and dry deposition of gases and particles. Atmospheric reactions of organic compounds, with emphasis on toxics. Theoretical and experimental methods for determination of atmospheric lifetimes and products of chemicals. Cross-listed with ENTX 244.

CHEM 245. Chemistry and Physics of Aerosols. (3)

Lecture, three hours. Prerequisite(s): CHEM 109, CHEM 110B; or consent of instructor. Fundamentals of chemical and physical processes controlling behavior and properties of airborne particles. Topics include particle mechanics; electrical, optical, and thermodynamic properties; nucleation; surface and aqueous-phase chemistry; gas particle partitioning; sampling; size and chemical analysis; atmospheric aerosols; and environmental effects. Cross-listed with ENTX 245 and SWSC 245.

CHEM 246. Fate and Transport of Chemicals in the Environment. (4)

Prerequisite(s): CHEM 109 or CHEM 110B; CHEM 112A-CHEM 112B-CHEM 112C; or consent of instructor. Identification of toxicants and their sources in the environment; equilibrium partitioning of chemicals in the environment (between air, water, soil, sediment, and biota) using physico-chemical properties; transport and chemical transformations of chemical compounds in air, water, and soil media. Includes case studies of fate and transport of selected toxic chemicals. Cross-listed with ENTX 200.

CHEM 250. Graduate Seminar in Chemistry. (1)

Seminar, one and a half hours. Prerequisite(s): graduate standing. Oral reports by graduate students, faculty, and visiting scholars on current research topics in chemistry. Graded Satisfactory (S) or No Credit (NC). Course is repeatable.

CHEM 251. Graduate Seminar in Analytical Chemistry. (2)

Seminar, two hours. Prerequisite(s): graduate student status. Oral reports and discussion by students, faculty, and visiting scholars on current research topics in analytical chemistry. The course is offered each quarter. Letter grades will be assigned to students presenting formal seminars; others will be graded Satisfactory (S) or No Credit (NC). Course is repeatable.

CHEM 252. Graduate Seminar in Inorganic Chemistry. (2)

Seminar, two hours. Prerequisite(s): graduate student status. Oral reports and discussion by students, faculty, and visiting scholars on current research topics in inorganic chemistry. Letter grades will be assigned to students presenting formal seminars; others will be graded Satisfactory (S) or No Credit (NC). Course is repeatable.

CHEM 253. Graduate Seminar in Organic Chemistry. (2)

Seminar, two hours. Prerequisite(s): graduate student status. Oral reports and discussion by students, faculty, and visiting scholars on current research topics in organic chemistry. Letter grades will be assigned to students presenting formal seminars; others will be graded Satisfactory (S) or No Credit (NC). Course is repeatable.

CHEM 254. Graduate Seminar in Physical Chemistry. (2)

Seminar, two hours. Prerequisite(s): graduate student status. Oral reports and discussion by students, faculty, and visiting scholars on current research topics in physical chemistry. The course is offered each quarter. Letter grades will be assigned to students presenting formal seminars; others will be graded Satisfactory (S) or No Credit (NC). Course is repeatable.

CHEM 257. Environmental Chemistry Seminar. (1)

Seminar, one hour. Prerequisite(s): graduate standing in Chemistry or Soil and Water Sciences. Oral presentations by visiting scholars and UCR faculty on current research topics in environmental chemistry, environmental sciences, and environmental toxicology. Graded Satisfactory (S) or No Credit (NC). Course is repeatable. Cross-listed with SWSC 257.

CHEM 260. Analysis of Single Cells and Subcellular Organelles. (2) F,W,S

Seminar, two hours. Prerequisite(s): graduate standing or consent of instructor. Focuses on the study of individual biological entities and biochemical processes at the cellular and subcellular levels. Special emphasis is placed on the use of capillary electrophoresis (separation parameters and detectors) for cellular analysis. Other topics include microscopy, cell culture, biochemistry, instrumentation design, and laser micromanipulators, as they related to single cells and single organelles. Letter grades are assigned to students who present a seminar or submit a term paper; other students are graded Satisfactory (S) or No Credit (NC) based on seminar participation. Lillard

CHEM 261. Scanning Probe Microscopy in Surface Science. (2)

Seminar, two hours. Prerequisite(s): graduate standing; consent of instructor. Focuses on theory and applications of scanning probe microscopy in surface science, including the use of scanning tunneling microscopy to image surfaces on the atomic and molecular length scale, and scanning probe techniques to investigate and control elementary steps of surface reactions. Reviews surface crystallography, electronic, and phononic band structure. Letter grades are assigned to students who present a seminar or submit a term paper; other students receive Satisfactory (S) or No Credit (NC) grades. Course is repeatable. Bartels

CHEM 262. Ultrafast Dynamics in Condensed Matter. (2)

Seminar, two hours. Prerequisite(s): consent of instructor. The extremely fast relaxation and dephasing of nuclear (vibrational) and electronic excitations in condensed matter are probed by the use of coherent spectroscopy using (sub-picosecond) light pulses. Decay mechanisms are studied by making spectroscopic measurements at cryogenic temperatures (approximately 1K) and at various high pressures (greater than 100 Kbar). Letter grades will be assigned to students who present a seminar or submit a term paper; others will be graded Satisfactory (S) or No Credit (NC). May be repeated for credit. Chronister

CHEM 263. Synthesis of Novel Molecules. (2)

Seminar, two hours. Prerequisite(s): consent of instructor. Study of the asymmetric synthesis of novel molecules with emphasis on the mechanism and design of enantioselective reactions. Letter grades will be assigned to students who present a seminar or submit a term paper; others will be graded Satisfactory (S) or No Credit (NC). May be repeated for credit. Angle

CHEM 264. Novel Synthesis in Inorganic Chemistry. (2)

Seminar, two hours. Prerequisite(s): graduate standing or consent of instructor. Discusses strategies for the synthesis of novel structures in bioinorganic coordination, organometallic, and materials chemistry. Letter grades are assigned to students who present a seminar or submit a paper; other students are graded Satisfactory (S) or No Credit (NC) based on seminar participation. Course is repeatable. Reed

CHEM 265. Raman Spectroscopy of Biological Systems. (2)

Seminar, two hours. Prerequisite(s): graduate standing or consent of instructor. Applications of Raman spectroscopy to the characterization of the structure and function of biological membranes and membrane proteins. Emphasis will be placed on resonance enhanced Raman scattering, including the theoretical origins of resonance enhancement. Letter grades will be assigned to students who present a seminar or submit a term paper; others will be graded Satisfactory (S) or No Credit (NC). Course is repeatable. Bocian

CHEM 266. Chemical Microsensors for In Situ Measurements. (2)

Seminar, two hours. Prerequisite(s): consent of instructor. The development and characterization of novel chemical microsensors. Analytical properties such as time response selectivity and sensitivity will be investigated and optimized for use in the measurement of dynamic chemical events in situ in the mammalian brain. Letter grades will be assigned to students who present a seminar or submit a term paper; others will be graded Satisfactory (S) or No Credit (NC). Course is repeatable. Kuhr

CHEM 267. Organic Electronic Materials. (2)

Seminar, two hours. Prerequisite(s): graduate standing or consent of instructor. A study of design, synthesis, purification, manufacture, and application of carbon-based electronic materials. Students who present a seminar or submit a term paper receive a letter grade; other students receive a Satisfactory (S) or No Credit (NC) grade. Course is repeatable. Haddon

CHEM 268. Organometallics in Organic Synthesis. (2)

Seminar, two hours. Prerequisite(s): consent of instructor. Synthesis and reactions of organometallic compounds with emphasis on development of new organic reactions. Letter grades will be assigned to students who present a seminar or submit a term paper; others will be graded Satisfactory (S) or No Credit (NC). May be repeated for credit. Midland

CHEM 270. Synthesis of Molecules of Biological and Theoretical Interest. (2)

Lecture, two hours. Prerequisite(s): consent of instructor. Synthesis, reactions, and properties of molecules of naturally occurring substances (e.g., vitamin D, retinal and other natural products) and molecules of theoretical interest (e.g., non-benzenoid aromatics, etc.). Discussions of modern synthetic approaches, reaction mechanisms and structure-activity relationships. Letter grades will be assigned to students who present a seminar or submit a term paper; others will be graded Satisfactory (S) or No Credit (NC). May be repeated for credit. Okamura

CHEM 271. Design, Synthesis, and Applications of Highly Conjugated Organic Systems. (2)

Seminar, two hours. Prerequisite(s): graduate standing or consent of instructor. Focuses on the design and synthesis of highly conjugated organic molecules and polymers for application in molecule-based devices such as sensors, light emitting diodes, and conductors. Letter grades are assigned to students who present a seminar or submit a term paper; other students are graded Satisfactory (S) or No Credit (NC). Course is repeatable. Marsella

CHEM 272. Characterization of Atmospheric Aerosol Systems. (2)

Seminar, two hours. Prerequisite(s): consent of instructor. The development of instrumentation for the detection of individual atmospheric aerosol particles in-situ. Emphasis on characterizing the chemistry of aerosol systems as a function of size and composition. Letter grades will be assigned to students who submit a term paper or present a seminar; others will be graded Satisfactory (S) or No Credit (NC). Course is repeatable.

CHEM 273. Bioanalytical Nuclear Magnetic Resonance Spectroscopy. (2)

Seminar, two hours. Prerequisite(s): consent of instructor. Development of Pulse Fourier transform NMR techniques and their application to the characterization of peptides, proteins and intact cells. Letter grades will be assigned to students who present a seminar or submit a term paper; others will be graded Satisfactory (S) or No Credit (NC). May be repeated for credit. Rabenstein

CHEM 274. Metal-Carbon Bond Synthesis. (2)

Lecture, one hour; discussion, one hour. Prerequisite(s): consent of instructor. Techniques of metal-carbon bond synthesis. Reactions of metal-carbon systems. Characterization of metal-carbon systems, especially by nuclear magnetic resonance. Letter grades will be assigned to students who present a seminar or submit a term paper; others will be graded Satisfactory (S) or No Credit (NC). May be repeated for credit. Rettig

CHEM 275. Bioorganic Chemistry of Nucleic Acids. (2)

Seminar, two hours. Prerequisite(s): consent of instructor. The design, synthesis, and evaluation of nucleotides with novel hydrogen-bonding capabilities as well as ogligonucleotides capable of regulating gene expression. Discussion of ribonucleic acid catalysis, including possible catalytic functions that have not yet been determined. Letter grades will be assigned to students who present a seminar or submit a term paper; others will be graded Satisfactory (S) or No Credit (NC). Course is repeatable. Switzer

CHEM 276. Enantioselective Homogeneous Catalysis. (2)

Seminar, two hours. Prerequisite(s): graduate standing or consent of instructor. Design and preparation of novel inorganic and organometallic compounds with applications to catalyst development, to novel catalytic processes, and to synthesis of organometallic materials. Discussions of current publications on homogeneous catalysis and reaction mechanisms. Focus on frontiers in catalysis in the overall context of synthetic methodologies. Letter grades are assigned to students who present a seminar or submit a term paper; other students are graded Satisfactory (S) or No Credit (NC). Hollis

CHEM 277. Surface Chemistry. (2)

Seminar, two hours. Prerequisite(s): consent of instructor. Discussions for new advances in surface science, concentrating mainly on the use of molecular level. Letter grades will be assigned to students who present a paper; others will be graded Satisfactory (S) or No Credit (NC). May be repeated for credit. Zaera

CHEM 278. Nuclear Magnetic Resonance: Theory, Techniques, and Applications. (2)

Seminar, two hours. Prerequisite(s): graduate standing or consent of instructor. Focuses on the development of solid-state and liquid-state nuclear magnetic resonance (NMR) as a probe of molecular structure, function, and dynamics with applications that range from chemistry to physics and biology. Letters grades are assigned to students who present a seminar or submit a term paper; other students are graded Satisfactory (S) or No Credit (NC) based on seminar participation. Course is repeatable. Mueller

CHEM 279. Molecular Spectroscopy. (2)

Seminar, two hours. Prerequisite(s): consent of instructor. Properties of excited states of molecules. Molecular photophysics and photochemistry. Theory of radiationless transitions. Kinetics and mechanism of excited state decay. Laser spectroscopy. Letter grades will be assigned to students who present a seminar or submit a term paper; others will be graded Satisfactory (S) or No Credit (NC). May be repeated for credit. Scott

CHEM 280. Chemistry and Biochemistry of Gaseous Molecules. (2)

Lecture, one hour; discussion, one hour. Prerequisite(s): consent of instructor. Reactions and properties of organic compounds and ions in the absence of bulk media. Preparative mass spectrometry and ion-molecule reactions. Molecular mechanisms in the sense of smell. Letter grades will be assigned to students who present a seminar or submit a term paper; others will be graded Satisfactory (S) or No Credit (NC). May be repeated for credit. Morton

CHEM 282. Elementary Processes in Atmospheric Chemistry. (2)

Seminar, two hours. Prerequisite(s): graduate standing or consent of instructor. Applies state-of-the-art laser techniques to investigate elementary processes in atmospheric chemistry. Emphasis is quantitative understandings of atmospheric free-radical intermediates, their photochemistry, and their reaction mechanisms. Letter grades are assigned to students who present a seminar or submit a term paper; other students are graded Satisfactory (S) or No Credit (NC). Course is repeatable. Zhang

CHEM 283. Development of Inorganic Solid State Materials. (2)

Seminar, two hours. Prerequisite(s): graduate standing; consent of instructor. Focuses on the development of advanced materials such as optical, electronic, and porous materials. Topics include synthetic methods, characterization techniques, property measurements, and device applications. Special emphasis is placed on the design of synthetic strategies for the discovery of new functional materials with novel properties. Letter grades are assigned to students who present a seminar or submit a term paper; other students receive Satisfactory (S) or No Credit (NC) based on seminar participation. Course is repeatable. Feng

CHEM 287. Colloquium in Neuroscience. (1)

Colloquium, one hour. Prerequisite(s): graduate standing or consent of instructor. Oral reports on current research topics in neuroscience with presentations by visiting scholars, faculty, and students. Graded Satisfactory (S) or No Credit (NC). Course is repeatable. Cross-listed with BCH 287, BIOL 287, BMSC 287, NRSC 287, and PSYC 287. Hatton in charge

CHEM 289. Special Topics in Neuroscience. (2)

Seminar, two hours. Prerequisite(s): graduate standing or consent of instructor. An interdisciplinary seminar consisting of student presentations and discussion of selected topics in neuroscience. Content and instructor(s) vary each time course offered. Letter grades will be assigned to students presenting formal seminars; others will be graded Satisfactory (S) or No Credit (NC). Course is repeatable. Cross-listed with BCH 289, BIOL 289, BMSC 289, ENTM 289, NRSC 289, and PSYC 289. Hatton in charge

CHEM 297. Directed Research. (1-6)

Prerequisite(s): consent of a staff member. Research in analytical, inorganic, organic, or physical chemistry under the direction of a member of the staff. A written report is required of the research study. Graded Satisfactory (S) or No Credit (NC).

CHEM 299. Research for Thesis or Dissertation. (1-12)

Prerequisite(s): consent of a staff member. Research in analytical, inorganic, organic, or physical chemistry under the direction of a member of the staff. This research is to be included as part of the dissertation. Graded Satisfactory (S) or No Credit (NC). Course is repeatable.

Lecture, one hour. The technique of oral presentation, emphasizing the problems that arise in chemistry laboratory and classroom situations. Designed primarily for new graduate students in the Chemistry Department. Graded Satisfactory (S) or No Credit (NC).

CHEM 302. Teaching Practicum. (1-2)

Lecture/laboratory, four to eight hours. Prerequisite(s): Limited to Chemistry Department teaching assistants and Associates-In Chemistry. Supervised teaching in undergraduate courses in Chemistry. Graded Satisfactory (S) or No Credit (NC). May be repeated for credit. Units are not applicable to degree unit requirements.

CHEM 403. Special Techniques in Chemical Research. (1)

Lecture, one hour. Prerequisite(s): graduate status and consent of instructor. The course will cover special techniques including spectroscopy, electronics, etc. used in chemical research. The course will be graded Satisfactory (S) or No Credit (NC). May be repeated for credit.