DEPARTMENT OF CHEMISTRY
1120 Natural Sciences
II; (949) 824-6018
Donald. R. Blake, Department Chair
Faculty
Ioan Andricioaei, Ph.D. Boston College, Assistant Professor of Chemistry (computational, physical, and theoretical chemistry, chemical biology, and chemical physics)
V. Ara Apkarian, Ph.D. Northwestern University, Professor of Chemistry (physical chemistry and chemical physics)
Ramesh D. Arasasingham, Ph.D. University of California, Davis, Lecturer with Security of Employment, Chemistry (chemical education and inorganic chemistry)
Donald R. Blake, Ph.D. University of California, Irvine, Department Chair and Professor of Chemistry, and Professor of Earth System Science (atmospheric, analytical, environmental chemistry, and radiochemistry)
Suzanne A. Blum, Ph.D. University of California, Berkeley, Assistant Professor of Chemistry (inorganic, organic, and organometallic chemistry)
Andrew S. Borovik, Ph.D. University of North Carolina, Chapel Hill, Department Vice Chair and Professor of Chemistry (inorganic, organometallic, organic, polymer, materials and nanoscience chemistry, and chemical biology)
David A. Brant, Ph.D. University of Wisconsin, Professor Emeritus of Chemistry (physical chemistry of biological macromolecules)
Kieron Burke, Ph.D. University of California, Santa Barbara, Professor of Chemistry and Physics (theoretical and computational chemistry, physical chemistry, and chemical physics)
A. Richard Chamberlin, Ph.D. University of California, San Diego, Department Chair and Professor of Pharmaceutical Sciences, and Professor of Chemistry and Pharmacology (organic synthesis and chemical biology)
Robert M. Corn, Ph.D. University of California, Berkeley, Professor of Chemistry and Biomedical Engineering (analytical, materials, nanoscience, physical and polymer chemistry, chemical biology, and chemical physics)
Robert J. Doedens, Ph.D. University of Wisconsin, Professor Emeritus of Chemistry (structural inorganic and organometallic chemistry)
Kimberly Edwards, Ph.D. University of California, Irvine, Lecturer with Potential Security of Employment, Chemistry (general chemistry)
William J. Evans, Ph.D. University of California, Los Angeles, Professor of Chemistry (synthetic inorganic and organometallic chemistry)
Patrick Farmer, Ph.D. Texas A & M University, Professor of Chemistry (analytical, inorganic materials, nanoscience, organometallic and polymer chemistry and chemical biology)
Barbara J. Finlayson-Pitts, Ph.D. University of California, Riverside, Director of AirUCI and UCI Distinguished Professor of Chemistry (atmospheric, analytical, environmental and physical chemistry, and chemical physics)
Fillmore Freeman, Ph.D. Michigan State University, Professor of Chemistry (computational, organic, and theoretical chemistry)
Filipp Furche, Ph.D. University of Karlsruhe (Germany), Associate Professor of Chemistry (computational, materials, nanoscience, physical, polymer and theoretical chemistry, and chemical physics)
Nien-Hui Ge, Ph.D. University of California, Berkeley, Assistant Professor of Chemistry (analytical and physical chemistry, and chemical physics)
R. Benny Gerber, Ph.D. Oxford University, Professor of Chemistry (atmospheric, computational, environmental, physical and theoretical chemistry, and chemical physics)
Zhibin Guan, Ph.D. University of North Carolina at Chapel Hill, Professor of Chemistry and Biomedical Engineering (materials, nanoscience, organic and polymer chemistry, and chemical biology)
Stephen Hanessian, Ph.D. Ohio State University, Director of Medicinal Chemistry and Pharmacology, and Professor of Pharmaceutical Sciences and Chemistry (organic chemistry)
Warren J. Hehre, Ph.D. Carnegie-Mellon University, Professor Emeritus of Chemistry (theoretical chemistry)
John C. Hemminger, Ph.D. Harvard University, Dean of the School of Physical Sciences and Professor of Chemistry (analytical, atmospheric, environmental, materials, nanoscience, physical, polymer, and surface chemistry, and chemical physics)
Alan F. Heyduk, Ph.D. Massachusetts Institute of Technology, Assistant Professor of Chemistry (inorganic and organometallic chemistry, and chemical biology)
Wilson Ho, Ph.D. University of Pennsylvania, Donald Bren Professor of Physics and Chemistry (experimental condensed matter physics, materials, nanoscience, physical and polymer chemistry)
Kenneth C. Janda, Ph.D. Harvard University, Associate Dean of the School of Physical Sciences and Professor of Chemistry (analytical, atmospheric, environmental and physical chemistry, spectroscopy, and chemical physics)
Elizabeth R. Jarvo, Ph.D. Boston College, Assistant Professor of Chemistry (inorganic, organic, and organometallic chemistry)
Susan M. King, Ph.D. Massachusetts Institute of Technology, Senior Lecturer in Chemistry (organic chemistry)
Matthew Law, Ph.D. University of California, Berkeley, Assistant Professor of Chemistry (analytical, inorganic, materials, nanoscience, physical and polymer chemistry, and chemical physics)
Andrej Luptak, Ph.D. Yale University, Assistant Professor of Pharmaceutical Sciences, Chemistry, and Molecular Biology and Biochemistry (chemical biology)
Vladimir A. Mandelshtam, Ph.D. Institute of Spectroscopy, Academy of Sciences of the U.S.S.R., Professor of Chemistry (computational, physical and theoretical chemistry, and chemical physics)
Craig C. Martens, Ph.D. Cornell University, Professor of Chemistry (computational, materials, nanoscience, physical, polymer and theoretical chemistry, and chemical physics)
Rachel W. Martin, Ph.D. Yale University, Assistant Professor of Chemistry and of Molecular Biology and Biochemistry (analytical and physical chemistry, chemical biology, and chemical physics)
Robert T. McIver, Jr., Ph.D. Stanford University, Professor Emeritus of Chemistry (physical and analytical chemistry)
George E. Miller, D. Phil. Oxford University, Senior Lecturer with Security of Employment Emeritus and Reactor Supervisor (analytical and radioanalytical chemistry, and chemical education)
Harold W. Moore, Ph.D. University of Illinois, Department Vice Chair and Professor Emeritus of Chemistry (organic chemistry and rational drug design)
Shaul Mukamel, Ph.D. Tel-Aviv University, UCI Chancellor's Professor of Chemistry (analytical, computational, materials, nanoscience, physical, polymer, and theoretical chemistry, and chemical physics)
Serguei A. Nizkorodov, Ph.D. University of Basel, Switzerland, Associate Professor of Chemistry (atmospheric, analytical, environmental and physical chemistry, and chemical physics)
James S. Nowick, Ph.D. Massachusetts Institute of Technology, Professor of Chemistry (organic, polymer, materials and nanoscience chemistry, and chemical biology)
Larry E. Overman, Ph.D. University of Wisconsin, UCI Distinguished Professor of Chemistry (inorganic, organic and organometallic chemistry, and chemical biology)
Reginald M. Penner, Ph.D. Texas A & M University, Director of the Center for Solar Energy and Professor of Chemistry (analytical, materials, nanoscience, physical, and polymer chemistry, and chemical physics)
Eric O. Potma, Ph.D. University of Groningen (The Netherlands), Assistant Professor of Chemistry (analytical and physical chemistry, chemical biology, and chemical physics)
Thomas L. Poulos, Ph.D. University of California, San Diego, UCI Chancellor's Professor of Molecular Biology and Biochemistry, Pharmaceutical Sciences, Physiology and Biophysics, and Chemistry (inorganic/organic chemistry)
Peter M. Rentzepis, Ph.D. Cambridge University, Professor of Chemistry and of Electrical Engineering and Computer Science, and UC Presidential Chair (physical chemistry, chemical physics, and picosecond spectroscopy)
F. Sherwood Rowland, Ph.D. University of Chicago, Donald Bren Research Professor Emeritus of Chemistry and Earth System Science (atmospheric, analytical and environmental chemistry, and radiochemistry)
Scott D. Rychnovsky, Ph.D. Columbia University, Professor of Chemistry (organic chemistry)
A. J. Shaka, Ph.D. Oxford University, Department Vice Chair and Professor of Chemistry (analytical and physical chemistry, chemical biology, and chemical physics)
Kenneth J. Shea, Ph.D. Pennsylvania State University, Professor of Chemistry and of Chemical Engineering and Materials Science (analytical, materials, nanoscience, organic, and polymer chemistry)
Mare Taagepera, Ph.D. University of Pennsylvania, Senior Lecturer with Security of Employment Emerita (physical organic chemistry and chemical education)
Douglas J. Tobias, Ph.D. Carnegie Mellon University, Department Vice Chair and Professor of Chemistry (computational biophysical chemistry)
Shiou-Chuan (Sheryl) Tsai, Ph.D. University of California, Berkeley, Associate Professor of Molecular Biology and Biochemistry and of Chemistry (organic chemistry and chemical biology)
Christopher D. Vanderwal, Ph.D. Scripps Research Institute, Assistant Professor of Chemistry (organic chemistry)
David L. Van Vranken, Ph.D. Stanford University, Professor of Chemistry (organic chemistry and chemical biology)
Gregory A. Weiss, Ph.D. Harvard University, Associate Professor of Chemistry and of Molecular Biology and Biochemistry (organic chemistry and chemical biology)
Keith A. Woerpel, Ph.D. Harvard University, Professor of Chemistry (organic and organometallic chemistry)
Max Wolfsberg, Ph.D. Washington University, Professor Emeritus of Chemistry (computational, physical and theoretical chemistry, and chemical physics)
Albert Yee, Ph.D. University of California, Berkeley, Professor of Chemical Engineering and Materials Science, Biomedical Engineering, and Chemistry
The major in Chemistry is elected by students planning careers in the chemical sciences and frequently also by those whose interests lie in biology, medicine, earth sciences, secondary education, business, and law. The curriculum of the Department is designed to satisfy the diverse needs of these students and others who may have occasion to study chemistry. The year course Chemistry 1A-B-C (or the Honors sequence Chemistry H2A-B-C) is prerequisite to all study in the Department at more advanced levels. The subject matter of this course serves also as a thorough introduction to the varied aspects of modern chemistry for students who do not wish to pursue their studies beyond the introductory level.
In order to enroll in Chemistry 1A, students must pass the Chemistry Placement Examination, which is given in late spring, summer, and during Welcome Week prior to the beginning of fall quarter. A preparatory course, Chemistry 1P, is offered in summer and fall for those who do not pass the Chemistry Placement Examination or who need additional preparation prior to entering Chemistry 1A. A grade of C or better in Chemistry 1P automatically qualifies the student for Chemistry 1A.
Completion of a one-year sequence in organic chemistry, either Chemistry 51A-B-C or H52A-B-C, is required for Chemistry majors and for students of the life sciences. Certain advanced courses required of Chemistry majors may also be of interest to others.
The undergraduate program of the Chemistry Department emphasizes close contact with research. Chemistry majors are urged to engage in research or independent study under the direction of a faculty member. Information describing the procedures for arranging an undergraduate research opportunity is available on the Chemistry Department Web site at http://www.chem.uci.edu/undergrad.
Much of the important chemical literature is being and has been printed in foreign languages, principally German, Russian, Japanese, Chinese, and French. Reading competence in one or more of these languages is desirable, and Chemistry majors are encouraged to acquire this competence.
Chemistry majors who are interested in teaching chemistry at the secondary level are urged to consider completing the optional concentration in Chemistry Education. A two-year post-baccalaureate program for the M.S. in Chemistry and a California Secondary Teaching Credential is described in the Chemistry Graduate Program section. Chemistry majors who plan subsequent study in medical, dental, or other professional schools should request information concerning admission requirements directly from the schools which they seek to enter. Counseling about preparation for a career in the health sciences is provided by the health science advisors in the School of Biological Sciences. Those intending to pursue graduate studies in chemistry should discuss their plans with a faculty member no later than the fall quarter of their senior year.
Admission to the Major
Students may be admitted to the Chemistry major upon entering the University as freshmen, via change of major, and as transfer students from other colleges and universities. Information about change of major policies is available in the Physical Sciences Student Affairs Office and at http://www.changeofmajor.uci.edu. For transfer student admission, preference will be given to junior-level applicants with the highest grades overall, and who have satisfactorily completed the following required courses: one year of general chemistry with laboratory and one year of approved calculus.
REQUIREMENTS FOR THE BACHELOR'S DEGREE
University Requirements: See pages 56–62.
School Requirements: None.
Departmental Requirements
Basic Requirements: Mathematics 2A-B-D, Physics 7C-D-E and 7LC-LD (or 7B-D-E and 7LB-LD), Chemistry 1A-B-C and M2LA-LB-LC (or H2A-B-C and H2LA-LB-LC), Chemistry 5, Chemistry 51A-B-C and 51LA-LB-LC (or H52A-B-C and H52LA-LB-LC), Chemistry 107 and 107L, Chemistry 131A-B-C (or 130A-B-C), Chemistry 151 and 151L.
Elective Requirements: At least five electives from the following lists, including at least two courses selected from the lecture list and two courses selected from the laboratory list. Lectures: Chemistry 125, 127, 128, 135, 137, 138, 177; and Chemistry courses numbered 201-205, 213-249, 262, 271, and 272; Biological Sciences 98 (Biochemistry), 99 (Molecular Biology); Earth System Science 122 (Atmospheric Dynamics), 130 (Physical Oceanography); Physics 111A-B (Classical Mechanics), 112A-B (Electromagnetic Theory); Engineering CBEMS110 (Reaction Kinetics and Reactor Design), CBEMS112 (Introduction to Biochemical Engineering), CBEMS120A (Momentum Transfer), CBEMS120B (Heat and Mass Transfer), CBEMS130 (Separation Processes), CBEMS135 (Chemical Process Control), CBEMS145 (Chemical Engineering Design), CEE162 (Introduction to Environmental Chemistry), CEE165 (Physical-Chemical Treatment Processes).
Laboratories: Biological Sciences M114L (Biochemistry Laboratory), M116L (Molecular Biology Laboratory), Chemistry 128L (Introduction to Chemical Biology Laboratory Techniques), 152 (Advanced Analytical Chemistry), 153 (Physical Chemistry Laboratory), 156 (Advanced Laboratory in Chemistry and Synthesis of Materials), 160 (Organic Synthesis Laboratory), 170 (Radioisotope Techniques), 177L (Medicinal Chemistry Laboratory), 180 (Undergraduate Research), Engineering CBEMS140A-B (Chemical Engineering Laboratory), Physics 120 (Electronics for Scientists), and 121 (Advanced Laboratory). (Chemistry 180 can be counted toward this requirement no more than once.)
At least three of the courses used to satisfy the Elective Requirement must be courses offered by the Chemistry Department, including at least one lecture course and one laboratory course.
Optional American Chemical Society Certification: For ACS Certification, the program must include Chemistry 128 or Biological Sciences 98; and two additional laboratory courses from the following list: Chemistry 128L, 152, 153, 156, 160, 180, or H180. These courses may not overlap with the upper-division laboratory elective requirement.
Optional Concentration in Biochemistry: The program must include Biological Sciences 97, 98, 99; Chemistry 128, 128L; and three advanced biology electives chosen from Biological Sciences D103, D104, D111L, D137, D147, D151, D152, E109, E112L, M114, M114L, M116, M116L, M121, M121L, M122, M122L, M124, M124L, M128, M130, M133, M137, M138, M140, M144, N110, and N132.
Optional Concentration in Chemistry Education: Chemistry majors interested in K-12 education are required to take one course in education theory (Education 173 or 176) and three two-unit seminar/fieldwork courses in science education (Physical Sciences 5, 105, and 106). Chemistry majors who wish to teach in California will ultimately need to pass both a general exam (California Basic Educational Skills Test, CBEST) and a set of science subject tests (California Subject Examination for Teachers, CSET).
High school science teachers in California are expected to have a broad range of general science knowledge. The General Science Subject test of the CSET exam covers astronomy, geodynamics, Earth resources, ecology, genetics and evolution, molecular biology and biochemistry, cell and organismal biology, waves, forces and motion, electricity and magnetism, heat transfer and thermodynamics, structure and properties of matter. Chemistry majors will be well prepared for the general science component of the CSET by taking two courses in biology (Biological Sciences 93 and 94), two courses in geo
sciences (Earth System Science 1 and 7), one course in astronomy (Physics 20A), and one course in biochemistry (Biological Sciences 98), which counts as a required chemistry elective). Alternatively, students can prepare for the General Science CSET exam through independent study. Interested students should consult the CSET Web site at http://www.cset.nesinc.com/index.asp.
HONORS PROGRAM IN CHEMISTRY
The Honors Program in Chemistry is a research-based program offered to selected Chemistry majors during their final year. Applicants to the program must have completed their junior year with a grade point average of at least 3.3 overall and in their Chemistry courses. They must also have demonstrated the potential of carrying out research of honors quality, as judged by the Chemistry faculty member who will supervise their research. Students in this program enroll in Honors Research in Chemistry (Chemistry H180A-B-C) throughout their senior year and submit a formal thesis late in the spring quarter. They also enroll in the Honors Seminar in Chemistry (Chemistry H181), in which they receive instruction in scientific writing and present a formal research seminar. Successful completion of Chemistry H181 satisfies the UCI upper-division writing requirement.
Students who complete these requirements, whose grade point average remains above the 3.3 standard, and whose research is judged to be of honors quality will graduate with Departmental Honors in Chemistry.
The Department also offers an Honors General Chemistry sequence, H2A-B-C. This course in general chemistry is designed for members of the Campuswide Honors Program (CHP) and other highly qualified students. It covers the same material as Chemistry 1A-B-C, but in greater depth.
Additional information is available from the Chemistry Undergraduate Program Office.
PLANNING A PROGRAM OF STUDY
The departmental requirements leave the student a great deal of latitude in choice of courses; the student can choose to pursue interests ranging from biochemistry on the one hand to chemical physics on the other. Many of the basic requirements above coincide with those of the School of Biological Sciences. For this reason a double major in Chemistry and Biological Sciences is popular. The Department is approved by the American Chemical Society to offer an undergraduate degree certified by the Society as suitable background for a career in chemistry or for graduate study in chemistry. While it is not mandatory, it is desirable for students to pursue a course of study that the Department judges to merit a certified degree. Specifically, the following courses must be included in the program of study: Chemistry 128 or Biological Sciences 98; and two laboratory courses from the list of upper-division laboratory courses that are not already required for the major: Chemistry 128L, 152, 153, 156, 160, 170, 177L, 180, or H180. These courses must be taken for a letter grade.
Students should consult with their academic advisors on courses of study. A Chemistry major normally takes Chemistry 1A-B-C and M2LA-LB-LC (or H2A-B-C and H2LA-LB-LC), Mathematics 2A-B-D, and required writing courses during the freshman year. Students are encouraged to enroll in at least one freshman seminar during the freshman year; freshman seminars probe timely scientific topics and allow students to interact with faculty in an intimate environment. The sophomore year should include Chemistry 5, 51A-B-C, and 51LA-LB-LC (or H52A-B-C and H52LA-LB-LC); the Physics 7 sequence should be completed no later than the fall quarter of the junior year. The balance of the freshman and sophomore program can be chosen at the student's discretion with consideration given to progress toward completion of the UCI general education requirement.
In the junior year all Chemistry majors should enroll in a year sequence of physical chemistry and in Chemistry 151/151L (fall), 107 (winter), and 107L (spring). Chemistry 130A-B-C and 131A-B-C are equivalent courses in physical chemistry. They have the same prerequisites and expect the same level of chemical and mathematical rigor. Both are acceptable to satisfy the physical chemistry requirement for the major. Chemistry 131A-B-C develops the topic beginning from a molecular or microscopic point of view and proceeds to the macroscopic description of matter; applications may address primarily gas phase systems. Chemistry 130A-B-C, on the other hand, commences with the macroscopic description; this approach may be of particular interest for applications of physical chemistry in biology, materials science, and engineering. Students should choose between the two courses on the basis of their interests. Because of significant differences in the sequence of topics, students starting in one series may not switch to the other in subsequent quarters.
During the junior and senior years the Chemistry Department electives requirement should be fulfilled, as should other University and departmental requirements.
Sample programs for Chemistry majors, American Chemical Society-certified Chemistry majors, the Biochemistry concentration, the Chemistry Education concentration, and Chemistry-Biological Sciences double majors are shown in the accompanying charts. Sample programs for Chemistry majors wishing to emphasize chemical physics, computational or theoretical chemistry, chemical synthesis and reactivity, or materials or polymer science in their undergraduate programs are also available. All sample programs can be viewed on the Chemistry Department Web site at http://www.chem.uci.edu/undergrad.
The faculty encourages Chemistry majors to enhance their education by studying abroad for one or more quarters, or during the summer. In most cases, the Chemistry EAP advisor can help students plan a program of study that will not extend the time it takes to graduate. Also, study abroad can enhance students' applications for admission to graduate and professional schools. For more information about opportunities to study abroad, see the Center for International Education section of this Catalogue or visit the Physical Sciences Student Affairs Office.
Sample Program —
Chemistry Majors1
Items in parentheses are recommended
choices or alternatives.
| FALL | WINTER | SPRING |
| Freshman | ||
| Chemistry 1A, M2LA (H2A, H2LA) | Chemistry 1B, M2LB (H2B, H2LB) | Chemistry 1C, M2LC (H2C, H2LC) |
| Mathematics 2A | Mathematics 2B | Mathematics 2D |
| Gen. Ed. (Freshman Writing) | Gen. Ed. (Freshman Writing) | Gen. Ed. |
| Gen. Ed. | ||
| Sophomore | ||
| Chem. 51A, 51LA (H52A, H52LA) | Chem. 51B, 51LB(H52A, H52LA) | Chem. 51C, 51LC (H52C, H52LC) |
| Chemistry 5 | Physics 7C, 7LC (or 7B, 7LB) | Physics 7D, 7LD |
| Physics 2 (or 7A, 7LA) | Gen. Ed. | Gen. Ed. |
| Junior | ||
| Chem. 131A (130A) | Chem. 131B (130B) | Chem. 131C (130C) |
| Physics 7E | Chemistry 107 | Chemistry 107L |
| Chemistry 151, 151L | Chemistry Elective | Chemistry Elective |
| Gen. Ed./Elective | Gen. Ed./Elective | |
| Senior | ||
| Chemistry Elective | Chemistry Elective | Chemistry Elective |
| Gen. Ed./Elective | Gen. Ed./Elective | Gen. Ed./Elective |
| Gen. Ed./Elective | Gen. Ed./Elective | Gen. Ed./Elective |
| Gen. Ed./Elective | Gen. Ed./Elective | Gen. Ed./Elective |
1For ACS Certification, the program must include Chemistry 128 or Biological Sciences 98; and two additional laboratory courses from the following list: Chemistry 128L, 152, 153, 156, 160, 180, or H180. These courses may not overlap with the upper-division laboratory elective requirement.
Sample Program —
Concentration in Biochemistry
Items in parentheses are recommended choices
or alternatives.
| FALL | WINTER | SPRING |
| Freshman | ||
| Chemistry 1A, M2LA (H2A, H2LA) | Chemistry 1B, M2LB (H2B, H2LB) | Chemistry 1C, M2LC (H2C, H2LC) |
| Mathematics 2A | Mathematics 2B | Mathematics 2D |
| Gen. Ed. (Freshman Writing) | Gen. Ed. (Freshman Writing) | Gen. Ed. |
| Gen. Ed. | ||
| Sophomore | ||
| Chem. 51A, 51LA (H52A, H52LA) | Chem. 51B, 51LB (H52B, H52LB) | Chem. 51C, 51LC (H52C, H52LC) |
| Chemistry 5 | Physics 7C, 7LC (or 7B, 7LB) | Physics 7D, 7LD |
| Physics 2 (or 7A, 7LA) | Biological Sciences 98 | Biological Sciences 99 |
| Biological Sciences 97 | ||
| Junior | ||
| Chem. 130A (131A) | Chemistry 130B (131B) | Chemistry 130C (131C) |
| Physics 7E | Chemistry 107 | Chemistry 107L |
| Chemistry 151, 151L | Chemistry 128 | Chemistry 128L |
| Gen. Ed./Elective | Gen. Ed./Elective | |
| Senior | ||
| Advanced Bio. Elective | Advanced Bio. Elective | Chemistry Elective |
| Gen. Ed./Elective | Gen. Ed./Elective | Advanced Bio. Elective |
| Gen. Ed./Elective | Gen. Ed./Elective | Gen. Ed./Elective |
| Gen. Ed./Elective |
Sample Program —
Concentration in Chemistry Education1
Items in parentheses
are recommended choices or alternatives.
| FALL | WINTER | SPRING |
| Freshman | ||
| Chemistry 1A, M2LA (H2A, H2LA) | Chemistry 1B, M2LB (H2B, H2LB) | Chemistry 1C, M2LC (H2C, H2LC) |
| Mathematics 2A | Mathematics 2B | Mathematics 2D |
| Gen. Ed. (Freshman Writing) | Gen. Ed. (Freshman Writing) | Elective3 |
| Physical Sciences 52 | ||
| Sophomore | ||
| Chemistry 51A, 51LA (H52A, H52LA) | Chemistry 51B, 51LB (H52B, H52LB) | Chemistry 51C, 51LC (H52C, H52LC) |
| Chemistry 5 | Physics 7C, 7LC (or 7B, 7LB) | Physics 7D, 7LD |
| Physical Sciences 1052 | Biological Sciences 943 | Gen. Ed. |
| Biological Sciences 933 | ||
| Junior | ||
| Chemistry 131A (130A) | Chemistry 131B (130B) | Chemistry 131C (130C) |
| Physics 7E | Chemistry 107 | Chemistry 107L |
| Chemistry 151, 151L | Biological Sciences 984 | Physics 20A3 |
| Physical Sciences 1062 | Gen. Ed. | Gen. Ed. |
| Senior | ||
| Chemistry Lab | Chemistry Lab | Chemistry Lab/Lecture |
| Chemistry Lecture | Gen. Ed. | Education 173 or 1762 |
| Earth System Science 13 | Elective3 | Gen. Ed. |
| Elective3 | Gen. Ed. | Gen. Ed. |
1For ACS
Certification, the program must include Chemistry 128 or Biological Sciences 98;
and two additional laboratory courses from the following list: Chemistry 128L, 152,
153, 156, 160, 180, or H180. These courses may not overlap with the upper-division
laboratory elective requirement.
2Courses required for concentration
in Chemical Education. Students who do not place out of Physics 2 (or 7A and 7LA)
should take it as their Year 1 elective.
3Free elective.
4Counts
as an upper-division Chemistry elective.
Sample Program —
Chemistry-Biological Sciences Double Majors
Items in parentheses are recommended
choices or alternatives.
| FALL | WINTER | SPRING |
| Freshman | ||
| Chemistry 1A, M2LA (H2A, H2LA) | Chemistry 1B, M2LB (H2B, H2LB) | Chemistry 1C, M2LC (H2C, H2LC) |
| Mathematics 2A | Mathematics 2B | Mathematics 2D |
| Bio. Sci. 93 | Bio. Sci. 94 | Bio. Sci. 2B |
| Gen. Ed. (Freshman Writing) | Gen. Ed. (Freshman Writing) | Gen. Ed. |
| Bio. Sci. 2A | ||
| Sophomore | ||
| Chem. 51A, 51LA (H52A, H52LA) | Chem. 51B, 51LB (H52B, H52LB) | Chem. 51C, 51LC (H52C, H52LC) |
| Bio. Sci. 194S | Physics 7C, 7LC (or 7B, 7LB) | Physics 7D, 7LD |
| Physics 2 (or 7A, 7LA) | Bio. Sci. 98 | Bio. Sci. 99 |
| Bio. Sci. 97 | Gen. Ed./Elective | Chemistry 5 |
| Junior | ||
| Chem. 130A (131A) | Chem. 130B (131B) | Chem. 130C (131C) |
| Physics 7E | Chemistry 107 | Chemistry 107L |
| Chemistry 151, 151L | Required Bio. Sci. major course | Required Bio. Sci. major course |
| Bio. Sci. 100L | Gen. Ed./Elective | Gen. Ed./Elective |
| Senior | ||
| Required Bio. Sci. major course | Chemistry Elective | Chemistry Elective |
| Bio. Sci. Lab | Bio. Sci. Elective | Chemistry Elective |
| Gen. Ed./Elective | Bio. Sci. Lab | Bio. Sci. Lab |
| Gen. Ed./Elective | Gen. Ed./Elective |
The Department offers the M.S. and Ph.D. degrees in Chemistry. The Ph.D. degree is granted in recognition of breadth and depth of knowledge of the facts and theories of modern chemistry and an ability to carry out independent chemical research demonstrated through submission of an acceptable doctoral dissertation. The M.S. degree may be earned either through submission of an acceptable Master's thesis (Plan I) or through an approved program of graduate course work and a comprehensive oral examination (Plan II). A Master's degree is not a prerequisite for admission to the Ph.D. program.
Students in the Ph.D. and M.S. Plan I (Thesis) programs are required to complete a minimum of seven approved courses (or 28 units), including six graduate-level courses (or 24 units), in chemistry. The M.S. Plan II (Non-Thesis) program requires that the student complete 10 graduate-level chemistry courses (or 40 units) and a comprehensive oral examination. Graduate students are expected to attain grades of B or better to remain in good academic standing. The comprehensive oral examination assesses the competence of the candidate in the areas of chemistry covered by the chosen course work, with unanimous agreement among the three examination committee members required for satisfactory completion.
Progress toward the Ph.D. degree during the first year is assessed by a written examination administered after completion of the first year of study. This examination covers either research accomplishments during the first year or comprehensive knowledge acquired in course work. The time and content of the examination depends upon the student's specific area of interest.
Training in teaching is an integral part of each graduate program, and all graduate degree candidates are expected to participate in the teaching program for at least four quarters during their graduate career.
Participants in the Ph.D. program take an oral examination for formal Advancement to Candidacy. This examination consists of an oral defense before a faculty committee of the student's dissertation research project, and an original research proposition conceived, developed, and documented by the student. The committee may examine the student at this time on any subject it deems relevant to the independent pursuit of chemical research. The normative time for advancement to candidacy is three years.
The most important component of the Ph.D. program is the doctoral dissertation, which must describe the results of original research performed by the student under the supervision of a faculty member of the Department. The criterion for acceptability of the dissertation is that its contents be of a quality suitable for publication in a scientific journal of high editorial standards. Each Ph.D. candidate is expected to present the work described in the completed dissertation in a seminar before the Department, following which the candidate will be examined on the contents of the dissertation by a committee of the faculty. A Master's thesis presented in partial fulfillment of the requirements for the M.S. under Plan I must also describe the results of a student's original research performed under the direction of a faculty member. However, no public oral defense of the Master's thesis is required.
Residency requirements specify a minimum of six quarters in residence at UCI for Ph.D. candidates and three quarters for M.S. candidates.
The normative time for completion of the Ph.D. is five years, and the maximum time permitted is seven years.
MASTER OF SCIENCE IN CHEMISTRY WITH A TEACHING CREDENTIAL
In cooperation with the UCI Department of Education, the Chemistry Department sponsors a coordinated two-year program for the M.S. degree in Chemistry and the California Single Subject Teaching Credential. The M.S. degree may be obtained under either Plan I or Plan II described below. Prospective graduate students interested in this program should so indicate on their graduate application and should request a detailed description of the program from the Chemistry Department Graduate Affairs Office or the Department of Education.
The following lists specify requirements for each of the graduate programs offered by the Department of Chemistry.
MASTER OF SCIENCE IN CHEMISTRY PLAN I
(Thesis Plan)
Completion of a minimum of seven approved courses (or 28 units), including six graduate-level courses (or 24 units) in chemistry (as specified by the Department and excluding Chemistry 280, 290, 291, and 399) with maintenance of an average grade of B or better in all course work undertaken.
Completion of the teaching requirement.
Completion of three quarters in residence at UCI.
Submission of an acceptable Master's thesis.
MASTER OF SCIENCE IN CHEMISTRY PLAN II
(Non-Thesis Plan)
Completion of 10 graduate-level courses (or 40 units) in chemistry (excluding Chemistry 290, 291, and 399 and counting Chemistry 280 no more than once) with an average grade of B or better.
Maintenance of an average grade of B or better in all course work undertaken.
Completion of the teaching requirement.
Completion of three quarters in residence at UCI.
Satisfactory completion of a comprehensive oral examination.
DOCTOR OF PHILOSOPHY IN CHEMISTRY
Completion of a minimum of seven approved courses (or 28 units), including six graduate-level courses (or 24 units) in chemistry (as specified by the Department and excluding Chemistry 280, 290, 291, and 399) with maintenance of an average grade of B or better in all course work undertaken.
Completion of the second-year Examination requirement.
Completion of the Oral Examination requirement for Advancement to Candidacy.
Completion of the teaching requirement.
Completion of six quarters in residence at UCI.
Submission of an acceptable doctoral dissertation.
Area Requirements
Ph.D. students generally choose from one of six areas of specialization in the Department which determines course work requirements. Generally, each area requires three or four core courses and a menu of additional courses from which to choose to reach the required total of seven courses.
Analytical Chemistry: Three core courses: Chemistry 243, 246, and 249; plus four additional courses from Chemistry 213, 230, 231A, 232A, 233, 234, 247, 248, 271, and 272.
Atmospheric Chemistry: Three core courses: Chemistry 213, either Chemistry 231A or 232A, and Chemistry 245; plus four additional courses from Chemistry 230, 231A, 231B, 232A, 234, 241, and 243, 246, 249, and Earth System Science 208A and 208B.
Chemical and Structural Biology-Bioinorganic: Five required courses: Chemistry 215, 217, 218, 219, and Molecular Biology and Biochemistry 204. Two additional courses from: Chemistry 201, 202, 203, 204, 205, 216, 220, 222, 227, 231A, 231B, 231C, 232A, 232B, 232C, 243, 249, 253, 271, and Molecular Biology and Biochemistry 208, 211, 223, and 254.
Chemical and Structural Biology-Bioorganic: Five required courses: Chemistry 201, 204, 219, and Molecular Biology and Biochemistry 203 and 204. Two additional courses from: Chemistry 202, 203, 205, 215, 216, 218, 220, 222, 227, 231A, 231B, 231C, 232A, 232B, 232C, 243, 249, 253, 271, and Molecular Biology and Biochemistry 208, 211, 223, and 254.
Chemical and Structural Biology-Biophysical: Five required courses: Chemistry 219, 221A, 231A, 232A, and Molecular Biology and Biochemistry 204. Two additional courses from: Chemistry 201, 202, 203, 204, 205, 215, 216, 218, 220, 222, 227, 231B, 231C, 232B, 232C, 243, 249, 253, 271, and Molecular Biology and Biochemistry 208, 211, 223, and 254.
Chemical and Structural Biology-Structural: Five required courses: Chemistry 219 and Molecular Biology and Biochemistry 203, 204, 211, and one of the following: Chemistry 218, 220, 221A. Two additional courses from: Chemistry 201, 202, 203, 204, 205, 215, 216, 218, 220, 222, 227, 231A, 231B, 231C, 232A, 232B, 232C, 243, 249, 253, 271, and Molecular Biology and Biochemistry 208, 223, and 254.
Inorganic Chemistry: Three core courses: Chemistry 215, 216, and 217; plus four additional courses from Chemistry 201, 202, 203, 204, 205, 220, 225, and 249, Molecular Biology and Biochemistry 203, 204, and 207, Biological Chemistry 210A and 212.
Organic Chemistry: Three core courses: Chemistry 201, 203, and 204 or 220; plus four additional courses from Chemistry 202, 205, 215, 216, 217, 218, 220, and 225, Molecular Biology and Biochemistry 203, 204, and 207, Biological Chemistry 210A and 212, Physiology and Biophysics 204 and 242.
Physical Chemistry: Three core courses: Chemistry 213, 231A, and 232A; plus four additional courses from Chemistry 207, 227, 230, 231B, 231C, 232B, 232C, 234, 235, 236, 248, 249, and 266.
CONCENTRATION IN CHEMICAL AND MATERIALS PHYSICS
This is an interdisciplinary program between condensed matter physics and physical chemistry, which is designed to eliminate the barrier between these two disciplines. Students with B.S. degrees in Physics, Chemistry, or Materials Science and Engineering, are encouraged to apply to the program. The goal of the concentration in Chemical and Materials Physics (ChaMP) is to provide students with a broad interdisciplinary education in the applied physical sciences that emphasizes modern laboratory and computational skills. The program accepts students for both the M.S. and the Ph.D. degrees. Upon admission to the program, students are assigned two faculty advisors, one from the Department of Physics and Astronomy, and one from the Department of Chemistry, to provide guidance on curriculum and career planning.
The curriculum for the M.S. program includes a summer session to assimilate students with different undergraduate backgrounds; formal shop, laboratory, and computational courses; a sequence on current topics to bridge the gap between fundamental principles and applied technology; and a course to develop communication skills. The required courses include thirteen core courses and three electives (subject to advisor approval) as follows: Core: Chemistry 206, 208, 229A, 231A-B-C, 232A-B, 266; two courses from the following group: Chemistry 228, 230, Physics 211, 222; one course from each of the following two groups: Physics 133 or 238A or Chemistry 236; Physics 273 or Chemistry 273 or Physical Sciences 139. Electives: Chemistry 213, 225, 226, 229B, 232C, 233, 243, 248, 249, Engineering EECS278, EECS285B, MSE201, MSE259A, Physics 134, 213C, 223, 224, 226, 229B, 233A-B, 238A. In addition to the required courses, M.S. students complete a master's thesis. Students are required to advance to candidacy for the master's degree at least one quarter prior to filing the master's thesis. There is no examination associated with this advancement, but the thesis committee needs to be selected and appropriate forms need to be filed. The M.S. program prepares students to compete for high-tech jobs or to begin research toward a Ph.D. degree.
Successful completion of the M.S. degree requirements qualifies students for the Ph.D. program. Progress toward the Ph.D. degree is assessed by a written comprehensive examination administered in the summer after completion of the first year of study. This examination covers comprehensive knowledge acquired in course work, and the content of the examination depends upon the student's specific area of interest.
Participants in the Ph.D. program take an examination for formal advancement to candidacy. It is typically taken within one year of successful completion of the comprehensive examination. To satisfy normative progress toward the degree, it must be taken by the end of the student's third year. The examination is comprised of two parts: (a) a written report on a topic to be determined in consultation with the research advisor and (b) an oral report on research accomplished and plans for completion of the Ph.D. dissertation.
GRADUATE GATEWAY PROGRAM IN MEDICINAL CHEMISTRY AND PHARMACOLOGY (MCP)
The one-year graduate Gateway Program in Medicinal Chemistry and Pharmacology (MCP) is designed to function in concert with selected department programs, including the Ph.D. in Chemistry. Detailed information is available in the Department of Pharmaceutical Sciences section on page 538, and online at http://www.cohs.uci.edu/pharm.shtml.