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.

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. Particular attention will be devoted to the intrinsic (structure, chemistry) and extrinsic (processing, microstructure) material features that determine these properties. Prerequisite: PHYS 2415 or equivalent.

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 pool characteristics, defects, as well as the impact on resulting materials properties based on the processing-structure-property relationships. Prerequisite: MSE 3070

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

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 universal to all polymeric systems across various length scales and can be applied to both synthetic and biopolymers. Thus, this course can serve as general guidance for the design and development of soft (bio) materials. Pre-requisite: MSE 3050 or CHE 3316 or MAE 2100 or instructor permission

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 understood based on continuum fracture mechanics and microstructural damage mechanisms. Prerequisite: MSE 3060

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.

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 major engineering design problem. Students will apply principles of engineering design to generate iterative concept and design reports in written and oral form.  Co-requisite: STS 4500; Pre-requisite: APMA 3110, MSE 2101, 3050, 3060, 3070, and 3101.

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.