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, and materials processing. Case studies include materials for aero turbine engines and ultralight structures. Prerequisite CHEM 1410 or 1610 or CHEM 1810. Corequisite MAE 2310 or CE 2310.

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 magnetism. Point defects, dislocations, and interfaces are introduced along with the thermodynamic and kinetic principles that govern their interactions and roles during materials processing and application. Prerequisite: APMA 2120 or MATH 2310

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 fuel cell systems using various energy materials including ion and solid-state lithium. Explains corrosion in recycling/sustainability as well as degradation and failure of functional and structural materials. Pre-requisite: CHEM 1410 or equivalent.

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 viewpoint. Material systems (polymers, metals, ceramics, and electronic) are developed sequentially to provide a framework to explain the fundamental, physical origins of observable and important macro scale properties.

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 thermodynamic concepts to phase diagrams and construction of phase diagrams from thermodynamic data, (3) discussion of the thermodynamics of interfaces and the role the interfaces play in phase transformations. Prerequisite: APMA 2120 or MATH 2310.

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 and Helmholtz functions to equilibrium systems, reactions, and phase diagrams. Atomistic and statistical mechanical interpretations of crystalline and non-crystalline solids are linked to the general thermodynamical laws by the partition function. Nonequilibrium and irreversible processes in solids are discussed. Prerequisite: Instructor permission.

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 attention is given to the nature of the crystalline state and wave-particle diffraction with a strong emphasis on the reciprocal lattice, tensor, and Brillouin Zone concepts.

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.

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 will examine mechanical, electrical and thermal properties of materials-what they mean, how they depend on structure, how to measure them, how to change them, and how to analyze the measurements. The course includes both a lecture and a lab. MSE 2090 required as a pre- or co-requisite.

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.