Special topic courses in Materials Science and Engineering

The course aims to let students learn how to perform the analysis of the key kinetic processes, phase transformations, and the development of microstructure in real materials. We will study the atomic mechanisms of diffusion and the analytical and numerical methods to describe diffusion, kinetics of phase transformations and formation of complex microstructure as defined by the interplay of thermodynamics and kinetics of mass transfer. Pre-requisite: MSE 3050 or Instructor Permission

This course examines the fundamental principles of physics, chemistry, materials science, and manufacturing which underlie the making, shaping, and fabrication of engineering components from casting and deformation processing (e.g. rolling, extrusion, forging) of metals, to powder processing of metals and ceramics, to polymer injection molding, to thin-film processing and lithography relevant to microelectronic circuit fabrication. Prerequisite: MSE 3070 or Instructor Permission

Introduction to classical atomic-level simulation techniques (molecular dynamics, Metropolis and kinetic Monte Carlo). The basic concepts, capabilities and limitations of the methods are discussed, an overview of the state-of-the-art is provided, and examples of recent success stories are considered. The emphasis is on getting practical experience in designing and performing simulations. Prerequisite: 3rd year standing or instructor permission. Prerequisite: 3rd year standing or instructor permission.

Advanced undergraduate course on topics not normally covered in other course offerings. The topic usually reflects new developments in the materials science and engineering field. Offerings are based on student and faculty interests.

A fourth-year project in MSE, under the supervision of a faculty member, is designed to give undergraduate students an application of principles learned in the classroom. The work may be experimental or computational, and the student is expected to become proficient in techniques used to process, characterize, or model materials. The project should make use of design principles in the solution of a problem. Prerequisite: Instructor permission.

Provides a fundamental understanding of the structure of crystalline and non-crystalline engineering materials from electronic to macroscopic properties. Topics include symmetry and crystallography, the reciprocal lattice and diffraction, quantum physics, bonding and band theory. Prerequisite: Instructor permission.

Basic course designed to provide a foundation for correlating defect structure and microstructure with physical, mechanical and chemical properties of engineering materials. The fundamental properties of point, line and surface defects in ordered media will be formulated. The thermodynamics of point defects in various types of solids will be discussed as well as the geometry and mechanics of crystal dislocations and their role in crystal plasticity elucidated. The essential elements of microstructure will be characterized emphasizing the concepts of phase constitution, microconstituent, polycrystalline aggregate and multiphase materials. The concept of real materials embodying a hierarchy of structures is emphasized. The principles governing the genesis and stability of material structure at various levels will be discussed. Prerequisite: MSE 6010.

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.

Provides a fundamental understanding of a broad spectrum of techniques utilized to characterize properties of solids. The methods used to assess properties are described through integration of the basic principles and application. Methods more amenable to analysis of bulk properties are differentiated from those aimed at measurements of local/surface properties. MSE 3670 or equivalent, or a solid state materials/physics course.