This course will discuss structure, bonding, and properties of transition metal-containing molecules and inorganic solids. Students will examine structure and bonding in transition metal complexes through molecular orbital and ligand field theories, with an emphasis on the magnetic, spectroscopic, and thermodynamic properties of transition metal complexes. The class will also examine reactions of transition metal complexes, including the unique chemistry of organometallic compounds. The laboratory experiments complement lecture material and include an independent project.

This course will discuss structure, bonding, and properties of transition metal-containing molecules and inorganic solids. Students will examine structure and bonding in transition metal complexes through molecular orbital and ligand field theories, with an emphasis on the magnetic, spectroscopic, and thermodynamic properties of transition metal complexes. The class will also examine reactions of transition metal complexes, including the unique chemistry of organometallic compounds. The laboratory experiments complement lecture material and include an independent project.

This course will discuss structure, bonding, and properties of transition metal-containing molecules and inorganic solids. Students will examine structure and bonding in transition metal complexes through molecular orbital and ligand field theories, with an emphasis on the magnetic, spectroscopic, and thermodynamic properties of transition metal complexes. The class will also examine reactions of transition metal complexes, including the unique chemistry of organometallic compounds. The laboratory experiments complement lecture material and include an independent project.

This course will discuss structure, bonding, and properties of transition metal-containing molecules and inorganic solids. Students will examine structure and bonding in transition metal complexes through molecular orbital and ligand field theories, with an emphasis on the magnetic, spectroscopic, and thermodynamic properties of transition metal complexes. The class will also examine reactions of transition metal complexes, including the unique chemistry of organometallic compounds. The laboratory experiments complement lecture material and include an independent project.

The theory of quantum mechanics is developed and applied to spectroscopic experiments. Topics include the basic principles of quantum mechanics; the structure of atoms, molecules, and solids; and the interpretation of infrared, visible, and fluorescence spectra. Appropriate laboratory work will be arranged. Three hours of class and four hours of laboratory per week.

Requisite: CHEM 161 or 165, CHEM 221, MATH 121, PHYS 116 or 123. Limited to 24 students.

Fall semester: Professor Olshansky.

The theory of quantum mechanics is developed and applied to spectroscopic experiments. Topics include the basic principles of quantum mechanics; the structure of atoms, molecules, and solids; and the interpretation of infrared, visible, and fluorescence spectra. Appropriate laboratory work will be arranged. Three hours of class and four hours of laboratory per week.

Requisite: CHEM 161 or 165, CHEM 221, MATH 121, PHYS 116 or 123. Limited to 24 students.

Fall semester: Professor Olshansky.

The theory of quantum mechanics is developed and applied to spectroscopic experiments. Topics include the basic principles of quantum mechanics; the structure of atoms, molecules, and solids; and the interpretation of infrared, visible, and fluorescence spectra. Appropriate laboratory work will be arranged. Three hours of class and four hours of laboratory per week.

Requisite: CHEM 161 or 165, CHEM 221, MATH 121, PHYS 116 or 123. Limited to 24 students.

Fall semester: Professor Olshansky.

Independent reading or research course. A half course.

Admission with consent of the instructor. Omit 2023-24. The Department.

How to handle overenrollment: null

Students who enroll in this course will likely encounter and be expected to engage in the following intellectual skills, modes of learning, and assessment: The course emphasizes readings from the primary scientific literature, independent research, quantitative work, and laboratory work.

Independent reading or research course. Full course.

Admission with consent of the instructor. Fall and spring semesters. The Department.

How to handle overenrollment: null

Students who enroll in this course will likely encounter and be expected to engage in the following intellectual skills, modes of learning, and assessment: The course emphasizes readings from the primary scientific literature, independent research, quantitative work, and laboratory work.

In this discussion- and project-based course, students will learn about the historical context and systemic exclusion inherent to the development of western science. Students will explore the role that chemistry has played in human society and how social structures have, in turn, influenced the field of chemistry. With this context established, students will research contemporary strategies that are or have been employed to make the field of chemistry more inclusive within classroom and research settings.