Introduces the concepts of electrode potential, double layer theory, surface charge, and electrode kinetics. These concepts are applied to subjects that include corrosion and embrittlement, energy conversion, batteries and fuel cells, electro-catalysis, electroanalysis, electrochemical industrial processes, bioelectrochemistry, and water treatment. Prerequisite: Physical chemistry course or instructor permission.

Emphasizes the fundamental principles of transmission electron microscopy and illustrates its capabilities for characterizing the internal structures of materials by diffraction, imaging and spectroscopic techniques; includes weekly laboratory exercises. Prerequisite: MSE 6010 or instructor permission.

This course introduces the fundamentals of magnetism and magnetic materials, covering theory, modeling, characterization, and applications. Topics include magnetization, key interactions such as exchange coupling and magnetic anisotropy, and magnetic excitations. Magnetic properties are explained from an electronic-structure perspective, providing insight at the atomic and electronic levels. Students will gain the foundational knowledge needed to understand and design magnetic materials.

An introduction to basic kinetic processes in materials and develops basic mathematical skills necessary for materials research. Students learn to formulate the partial differential equations and boundary conditions used to describe basic materials phenomena in the solid state including mass and heat diffusion in single- and two-phase systems, the motion of planar phase boundaries, and interfacial reactions. Students develop analytical and numerical techniques for solving these equations and apply them to understanding microstructural evolution. Prerequisite: MSE 6230.

Deformation and fracture are considered through integration of materials science microstructure and solid mechanics principles over a range of length scales, emphasizing the mechanical behavior of metallic-structural alloys and electronic materials. Metal deformation is understood based on elasticity theory and dislocation concepts. Fracture is understood based on continuum fracture mechanics and microstructural damage mechanisms. Additional topics include fatigue, elevated temperature behavior, material embrittlement, time-dependency, experimental design, damage-tolerant life prognosis, small-volume behavior, and material property modeling. Prerequisite: MSE 4320, or BS in MSE, or MSE 6050, or permission of instructor for graduate students outside of MSE.

A study of special subjects related to developments in materials science under the direction of members of the staff. Offered as required under the guidance of a faculty member.

Analyzes the structure and thermodynamics of surfaces, with particular emphasis on the factors controlling chemical reactivity of surfaces; adsorption, catalysis, oxidation, and corrosion are considered from both theoretical and experimental viewpoints. Modern surface analytical techniques, such as Auger, ESCA, and SIMS are considered. Prerequisite: Instructor permission.

Broad topics and in-depth subject treatments are presented. The course is related to research areas in materials science and involves active student participation.

Detailed study of graduate course material on an independent basis under the guidance of a faculty member.

For master's students.