This course is primarily designed as a terminal course for non-science majors but is open to all students. Many of the traditional chemical theories are presented, but always in association with a topic of everyday interest. The selection and sequence of topics vary with the instructor and times. Labs illustrating applications are carried out where appropriate. A student who has received credit for CHEM 105 or CHEM 107 may not take CHEM 100 for credit without the registrar’s consent.
This course outlines the basic principles, laws and definitions of chemistry. Students learn atomic theory and basic reaction chemistry. Gas laws and enthalpy are also introduced. Laboratory work consists of experiments illustrating the above and offers an introduction to basic laboratory techniques. The course consists of both weekly lectures and scheduled laboratory. Prerequisite: one year of high school chemistry. Student must test into a math class higher than MATH 102 to enroll. Fall semester.
This course is a continuation of the topics presented in CHEM 105. Emphasis is on the study of ions in solutions and chemical equilibria. Both chemical kinetics and thermodynamics are covered. The course consists of weekly lectures and scheduled laboratory. Prerequisite: CHEM 105 or instructor’s consent. Spring semester.
An introductory course in the principles of quantitative techniques and calculations. Topics include statistics and acid-base chemistry, as well as acid-base, complexation and EDTA titrations. The weekly laboratory experiments are selected to provide experience in the analytical methods described in the lecture. Prerequisite: CHEM 107. Spring semester.
The purpose of this course is to introduce students to the basic language of organic chemistry. Selected topics include organic nomenclature, orbital hybridization, stereochemistry, and the chemistry of alkanes, alkenes and alkynes, and a few common instrumental methods (NMR, IR and GC-MS). Success in this course depends on students’ abilities to engage in a process that requires applying basic principles to the analysis of complex problems. Four lectures, one lab per week. Prerequisite: CHEM 107. Fall semester.
This course is intended for, but not limited to, students who are completing majors outside of chemistry (e.g. biology, environmental science or natural science). Selected topics include redox chemistry, carbonyl chemistry, aromatics, cycloadditions and the applications of instrumental methods (NMR, IR and GC-MS). In addition, select topics in bio-organic chemistry are covered to illustrate the application of mechanistic organic chemistry to the solution of problems of biochemical or medicinal interest. The lab component of the course serves to reinforce topics discussed during lectures. Prerequisite: CHEM 220.
This course is intended for, but not limited to, students who are completing a major in chemistry, including those pursuing the biochemistry concentration in the major. Selected topics include redox chemistry, carbonyl chemistry, aromatics, cycloadditions and a few common instrumental methods (NMR, IR and GC-MS). The course has an expanded, project-based laboratory. Prerequisite: grade of C or better in CHEM 220.
This course uses the principles of chemistry to understand natural systems and assess human impact on these systems. Lecture topics include atmospheric chemistry, the chemistry of natural aqueous systems, data collection and interpretation, and the chemistry of pollutants such as anthropogenic organic compounds and heavy metals. The laboratory aspect of the course focuses on analytical techniques commonly used in environmental analysis. Prerequisite: CHEM 107.
An in-depth study of properties, structures, bonding and reactions of inorganic compounds. Topics include molecular orbital theory, organometallics, coordination chemistry and catalysis. The weekly laboratory is designed to provide students with experience in inorganic synthesis and representative analytical methods of inorganic chemistry. Prerequisites: CHEM 211 and either CHEM 222 or CHEM 232.
An advanced special topics course in organic chemistry with emphasis on the mechanistic aspects of biomolecular action and drug design. Topics of discussion include anti-tumor agents, antibiotics, cholesterol-regulating agents, coenzymes and catalytic antibodies. Prerequisite: CHEM 222 or CHEM 232. Summer session, alternate years.
A study of modern methods for the asymmetric synthesis of organic compounds with emphasis on reaction mechanisms. Prerequisite: grade of C or better in CHEM 222 or CHEM 232.
The objectives of this course are to provide a conceptual understanding of instruments and instrumental methods and to provide hands-on experience in the lab. Four major topics are covered: spectrophotometric methods including ultraviolet-visible, atomic absorption, inductively coupled plasma and fluorescence spectroscopy; chromatographic separations including high-performance liquid chromatography and gas chromatography; electroanalytical methods including potentiometry, amperometry, coulometry and voltammetry; and mass spectrometry. Prerequisite: grade of C or better in CHEM 211. Spring semester.
The first semester of a year-long sequence utilizing the mathematical approach in the study of chemistry. Topics include the first, second and third laws of thermodynamics, the thermodynamics of ideal and real solutions, and an introduction to solution- and gas-phase kinetics. The laboratory experiments involve the application of these concepts to calorimetry, spectroscopy, electrochemistry, chemical kinetics and chemical equilibrium. Prerequisites: CHEM 211 and CHEM 222 or CHEM 232, MATH 132, PHYS 122 or (with instructor’s consent) PHYS 112. Fall semester.
This course introduces the concepts of quantum theory of atoms and molecules. The development of quantum mechanics is traced from the Bohr model of the atom to modern applications of computational chemistry. In the laboratory, students use computational chemistry and spectroscopy to illustrate the theoretical and mathematical concepts developed in the course. Prerequisite: CHEM 330. Spring semester.
The first half of the course covers the chemistry of carbohydrates, proteins, nucleic acids and lipids. Particular attention is given to enzyme kinetics and other methods available to study protein structure and function. The second half of the course focuses on bioenergetics and metabolism. Glycolysis, gluconeogenesis, the pentose phosphate pathway, citric acid cycle and oxidative phosphorylation are covered in detail. Weekly experiments are selected to provide experience in modern biochemical lab techniques. Students must present a paper published in the primary literature to their peers. Prerequisite: a grade of C or better in BIOL 244 (or instructor’s consent) and C or better in CHEM 222 or CHEM 232.
This course is designed as a continuation of CHEM 350. Topics include metabolism of lipids, proteins and nucleic acids, integration and regulation of metabolism, and photosynthesis. Students are expected to read and discuss current publications from the primary literature. In addition, students write a review article on an approved topic of their choice and present their findings to the class. The laboratory component of this course focuses on recombinant protein technologies. Prerequisite: grade of C or better in CHEM 350. Spring semester, alternate years.
Lecture, laboratory and/or literature studies at an advanced level. The intent is to provide students with the opportunity to increase their understanding of chemistry beyond the scope of the basic core courses. Representative topics include areas such as advanced biochemistry, organometallic chemistry, polymer chemistry and heterocyclic chemistry. Prerequisite: instructor’s consent.
A course that allows students to pursue research on an individual basis under the direction of a faculty member in chemistry. The specific topic of study is mutually agreed upon by the student and the faculty member directing the research. Prerequisite: instructor’s consent and approval of the associate dean of natural sciences.
An independent study course involving laboratory experiences under the direction of a faculty member in chemistry. A written report is due two weeks before the end of class. Students who wish to use a summer research experience performed at a site other than ÀÏ°ÄÃÅÁùºÏ²Ê¿ª½±¼Ç¼ as a substitute for CHEM 492 must have the discipline’s approval prior to undertaking the activity. Prerequisite: instructor’s consent.