The field of Materials Science drives technological innovations underlying all engineering fields. This course provides a scientific foundation to promote a rigorous understanding of materials from an atomistic to macroscopic …
The properties of any material help determine its ultimate usefulness to society. We can modify and manipulate properties by processing materials in different ways to control their structure. This class …
This course introduces state-of-the-art 3D printing and additive manufacturing techniques for metals, polymers, ceramics, and other materials. Students will be familiarized with both the fundamental science and industrial process, and …
We discuss how soft matter science, a new and growing area of materials science and engineering, underpins everyday cooking and haute cuisine. The goal is to use cooking to educate …
Special topic courses in Materials Science and Engineering
The course includes (1) an overview of classical thermodynamics necessary for understanding the conditions for phase equilibria, phase stability and phase transformations in one-component and multi-component systems, (2) application of …
Crystal structures of solids and their possible defects are examined. The structure-property paradigm is illustrated through discussion of the anisotropic properties of crystals, such as elasticity, thermal expansion, piezoelectricity, and …
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 …
Covers the principles of electrochemistry governing corrosion, batteries and fuel cells at the materials science and engineering level. Describes the basic electrochemistry, terminology, and performance of specific corrosion, battery and …
The course amplifies topics covered in introductory materials science through laboratory demonstration and experimentation. An understanding of modern instruments and experimental techniques including x-ray diffraction, optical and electron microscopy is …
Introduces physical-chemical-microstructural-mechanical property relations for aerospace materials. Metal, polymer, ceramic, and composite material systems are covered. Topics include strength, fracture, corrosion, oxidation/corrosion, materials selection, phase diagrams, kinetics of phase change, …
The course introduces the basics of materials interactions with electric and magnetic fields, including electromagnetic radiation. It describes the classes of materials that exhibit useful electronic, optical, and magnetic properties. …
This course introduces state-of-the-art additive manufacturing techniques for metallic materials, processing considerations, unresolved challenges and future opportunities. The course focuses on the underlying mechanisms such as energy-matter interaction, solidification, melt …
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, …
This course provides a rigorous understanding of polymers and polymeric materials from molecule to macroscopic viewpoint. Topics covered include single polymers, solutions, melts, gels, and networks. The knowledge obtained is …
Explores the microstructural origins of material deformation and fracture in response to mechanical loading. Deformation and creep are understood based on elasticity theory and dislocation concepts. Fatigue and fracture are …
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 …
This course is the first semester of a two-semester senior capstone design experience where groups of students bring together coursework fundamentals and laboratory practice skills to develop solutions to a …
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 …
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, …
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 …
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 …
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 …
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: …
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 …
Emphasizes the understanding of thermal properties such as heat capacity, thermal expansion, and transitions in terms of the entropy and the other thermodynamic functions. Develops the relationships of the Gibbs …
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 …
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 …
Develops the student's literacy in aluminum and titanium alloys used in the aerospace and automotive industries. Considers performance criteria and property requirements from design perspectives. Emphasizes processing-microstructure development, and structure-property …
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.
Emphasis placed on the applications of advanced techniques of transmission and scanning electron microscopy to modern research problems in materials science and engineering. Microdiffraction and microanalysis, lattice imaging, and convergent …
This course covers the physical principles governing the elastic, thermal, electronic, and optical properties of materials via a fundamental approach integrating materials science with concepts in solid state physics. Special …
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 …
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.
Formal record of student commitment to master's thesis research under the guidance of a faculty advisor. May be repeated as necessary.
For doctoral students.
Formal record of student commitment to doctoral research under the guidance of a faculty advisor. May be repeated as necessary.