Courses

CHEM 1008 reviews material presented in CHEM 2080 lectures and also provides problem-solving strategies and practice. This course is recommended for students who want to improve their chemistry problem-solving skills. CHEM 1008 is not a substitute for CHEM 2080 lectures and recitations.

Full details for CHEM 1008 - Academic Support for CHEM 2080

Reviews material presented in CHEM 3580 lectures and offers practice with CHEM 3580 material. Weekly review sessions focus on the most important topics covered in lecture and office hours held throughout the week are designed to help improve performance in CHEM 3580.

Full details for CHEM 1058 - Academic Support for CHEM 3580

This course centers on the critical reasoning skills required to solve first-year chemistry problems. Our Spring first-year chemistry class (CHEM 2080) presupposes an understanding of the basic quantitative reasoning skills required to solve chemistry problems and focus their limited lecture time instead on the teaching of chemistry knowledge. This course compensates for the fast pace of CHEM 2080.

Full details for CHEM 1080 - Introduction to Critical Thinking for the Sciences

Introduction to organic chemistry concepts with emphasis on structure, reactivity, and mechanisms of carbon compounds relevant to the life sciences.

Full details for CHEM 1570 - Introduction to Organic and Biological Chemistry

Covers fundamental chemical principles, with considerable attention given to the quantitative aspects and techniques important for further work in chemistry.

Full details for CHEM 2070 - General Chemistry I

Covers fundamental chemical principles, including reaction kinetics, thermodynamics, and equilibrium. These principles are presented quantitatively and explored in the laboratory. Considerable attention is given to the quantitative calculations and techniques important for further work in chemistry.

Full details for CHEM 2080 - General Chemistry II

Covers basic chemical concepts, such as reactivity and bonding of molecules, introductory quantum mechanics, and intermolecular forces in liquids and solids and gases. Attention will be focused on aspects and applications of chemistry most pertinent to engineering.

Full details for CHEM 2090 - Engineering General Chemistry

Introduction to the synthesis, separation, characterization, and handling of materials, including chromatography, extraction, crystallization, infrared spectroscopy, and others. An experiment is performed the first week of lab. Students need to enroll in the course Canvas site and complete the appropriate pre-lab assignments outlined on that site before coming to the first lab.

Full details for CHEM 2510 - Introduction to Experimental Organic Chemistry

Full details for CHEM 2780 - Methods in Chemical Education II

Survey of the methods basic to the experimental study of physical chemistry, with a focus on the areas of chemical equilibrium, kinetics, thermodynamics, and molecular spectroscopy.

Full details for CHEM 2900 - Introductory Physical Chemistry Laboratory

Introduction to the techniques of synthetic organic chemistry. A representative selection of the most important classes of organic reactions is explored in the first half of the semester, augmented by lectures on the reaction chemistry and the theory of separation and characterization techniques.

Full details for CHEM 3010 - Honors Experimental Chemistry I

Introduction to experimental physical chemistry, including topics in spectroscopy and kinetics. The analysis and numerical simulation of experimental data is stressed.

Full details for CHEM 3030 - Honors Experimental Chemistry III

The course emphasizes the important classes of organic compounds, with particular emphasis on their three-dimensional structures, mechanisms of their characteristic reactions, their synthesis, methods for their identification, and their applications in modern technology and medicine.

Full details for CHEM 3580 - Organic Chemistry for the Life Sciences

The course provides an intensive introduction to organic chemistry as a solid foundation for subsequent study in the fields of chemical, biological, materials and physical sciences. Students will learn a set of important tools and concepts that will enable appreciation and powerful application of modern organic chemistry.

Full details for CHEM 3590 - Honors Organic Chemistry I

CHEM 3900 is a continuation of CHEM 3890 and discusses the thermodynamic behavior of macroscopic systems in the context of quantum and statistical mechanics. After an introduction to the behavior of ensembles of quantum mechanical particles, the laws of thermodynamics, concepts of equilibrium, and chemical kinetics are covered in detail.

Full details for CHEM 3900 - Honors Physical Chemistry II

This course will introduce STEM students to the challenges of planning, financing, launching, and managing a new scientifically oriented business venture. The course focusses on case studies together with presentations by entrepreneurs in the chemical, pharmaceutical, and life sciences industries. Topics include new technology evaluation, IP assessment and management, business formation, resource allocation, personnel development, as well as manufacturing and sales issues

Full details for CHEM 4040 - Entrepreneurship in Chemical Enterprise

Discussion of chemical bonding and reactivity with an emphasis on the transition metals. A "ground up" approach will be taken, building bonding models from atomic electronic structure to molecular orbital theory. Course will also introduce concepts germane to solid state chemistry, bioinorganic chemistry, and organometallic catalysis.

Full details for CHEM 4100 - Inorganic Chemistry

Research in inorganic chemistry involving both laboratory and library work, planned in consultation with a faculty member.

Full details for CHEM 4210 - Introduction to Inorganic Chemistry Research

Research in analytical chemistry involving both laboratory and library work, planned in consultation with a faculty member.

Full details for CHEM 4330 - Introduction to Analytical Chemistry Research

Research in chemical biology involving both laboratory and library work, planned in consultation with a faculty member. To apply for independent research, please complete the on-line independent study form at data.arts.cornell.edu/as-stus/indep_study_intro.cfm.

Full details for CHEM 4430 - Introduction to Chemical Biology Research

Research in organic chemistry involving both laboratory and library work, planned in consultation with a faculty member.

Full details for CHEM 4610 - Introduction to Organic Chemistry Research

Research in physical chemistry involving both laboratory and library work, planned in consultation with a faculty member.

Full details for CHEM 4770 - Introduction to Physical Chemistry Research

This course provides a broad overview of modern computational methods in Chemistry. Topics covered will include investigating the statistical mechanics of condensed phase chemical systems using Monte Carlo and Molecular Dynamics, quantum mechanical characterization of molecular energetics and structure using Electronic Structure Theory (Hartree Fock, Perturbation Theory, and Density Functional Theory), and time-dependent approaches to investigate chemical reaction dynamics and kinetics.

Full details for CHEM 4810 - Computational Methods in Chemistry

In the Chemistry Honors Seminar students will present their research in written and oral form. The course will also include a broader discussion of professional issues and life skills in the world of chemistry.

Full details for CHEM 4980 - Honors Seminar

Full details for CHEM 5040 - Entrepreneurship in Chemical Enterprise

Supervision of Capstone Research Project.

Full details for CHEM 5120 - Capstone Research Project

This course provides a broad overview of modern computational methods in Chemistry. Topics covered will include investigating the statistical mechanics of condensed phase chemical systems using Monte Carlo and Molecular Dynamics, quantum mechanical characterization of molecular energetics and structure using Electronic Structure Theory (Hartree Fock, Perturbation Theory, and Density Functional Theory), and time-dependent approaches to investigate chemical reaction dynamics and kinetics.

Full details for CHEM 5810 - Computational Methods in Chemistry

An overview of physical methods applied in inorganic chemistry, including single-crystal x-ray diffraction, is given. The chemistry of the lanthanides and actinides, as well as nuclear chemistry is also presented.

Full details for CHEM 6060 - Advanced Inorganic Chemistry II

This course will provide a foundational background in the science of nanoscale materials, a research field that has been extremely active for more than twenty years. Simplified models of quantum mechanics, band theory, statistical mechanics, thermodynamics, and surface science will be presented. This theoretical background will be used to understand the structure and properties of inorganic materials, such as nanocrystals and nanowires, and organic materials, such as carbon nanotubes, graphene, and π-conjugated molecules. Previous exposure to quantum mechanics at the level of the Schrödinger equation will be assumed. The intended audience is first-year graduate students and upper-level undergraduate students in chemistry and related fields, including applied physics, physics, and materials/chemical/electrical/mechanical engineering.

Full details for CHEM 6090 - Nanomaterials: Chemistry and Physics

Application of NMR spectroscopy and high-resolution mass spectroscopy in organic chemistry, metabolomics, chemical biology, synthesis, inorganic chemistry, and polymer chemistry. Optional labs provide hands-on experience with NMR and MS instruments in the Cornell Chemistry Department and at Boyce Thompson Institute.

Full details for CHEM 6250 - Advanced Analytical Chemistry I

Modern techniques of organic synthesis; applications of organic reaction mechanisms and retrosynthetic analysis to the problems encountered in rational multistep synthesis, with particular emphasis on modern developments in synthesis design.

Full details for CHEM 6660 - Synthetic Organic Chemistry

Full details for CHEM 7650 - Physical Organic Chemistry and Determination of Reaction Mechanisms

Course will cover: 1) the physics of scattering and image formation, 2) macromolecular crystallography, 3) small-angle X-ray scattering, and 4) cryo-electron microscopy. Students will learn the theoretical principles of structural biology and gain practical experience with modern methods in data processing, structure determination, refinement, validation, and interpretation.

Full details for CHEM 7880 - Modern Methods in Structural Biology

The chief aim of this course is to provide an understanding of how the tools of modern spectroscopy can be applied to unravel the structural and dynamical properties of molecular systems, with a focus on optical techniques. The course will briefly cover the theoretical basis of light-matter interactions and factors governing the vibrational and electronic spectra of diatomic and polyatomic molecules. The main portion of the course will address current topics in spectroscopic research with a survey of different techniques and the theory behind them. By the end of the course, students will be equipped to understand and interpret the results of a wide array of steady-state and optical spectroscopic techniques applied to complex molecules.

Full details for CHEM 7910 - Advanced Spectroscopy

This is a course in time-dependent quantum mechanics that is concerned with the interaction of molecules with continuous-wave and pulsed irradiation.  The concepts covered in the course are an excellent starting point for a first principles understanding quantum computing.  Topics include: the density matrix; unitary time evolution, the evolution operator, two-level systems; non-unitary evolution, correlation functions, relaxation, dephasing processes, Bloch equations; time-dependent perturbation theory, average Hamiltonian theory, Fermi's Golden rule; multi-dimensional time-domain spectroscopy; Marcus-Jortner theory of electron transfer; electromagnetic radiation interacting with matter, Einstein coefficients, second quantization, stimulated emission, spontaneous emission, quantum optics.

Full details for CHEM 7940 - Quantum Mechanics II

Introduces the fundamentals of statistical mechanics: ensembles, distributions, averages, and fluctuations, building to the treatment of systems of interacting molecules. Topics from equilibrium statistical mechanics include structure and thermodynamics of molecular liquids, critical phenomena, and computational statistical mechanics. Topics from nonequilibrium statistical mechanics include spectroscopy, chemical kinetics, transport, and the microscopic origins of irreversibility.

Full details for CHEM 7960 - Statistical Mechanics