Courses
The listing of a course description here does not guarantee a course’s being offered in a particular semester. Please refer to the published schedule of classes on the Student Link for confirmation a class is actually being taught and for specific course meeting dates and times.
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ENG ME 801: Teaching Practicum I
PhD Requirement. Assist faculty by performing teaching or teaching-related duties, such as preparing and teaching labs and discussion sections, developing teaching materials, assisting with homework preparation and grading, proctoring exams, grading exams or papers. -
ENG ME 802: Teaching Practicum II
PhD requirement. Assist faculty by performing teaching or teaching-related duties, such as preparing and teaching labs and discussion sections, developing teaching materials, assisting with homework preparation and grading, proctoring exams, grading exams or papers. -
ENG ME 810: PhD Internship in Mechanical Engineering
This course provides ME PhD students the opportunity tom include a paid internship as part of their professional training. The internship must be related to the student's area of study. International students require CPT authorization. Written summary required. Graded P/F. Prerequisite: Permission of advisor and an approved internship offer; at least two complete semesters in the ME PhD program. Full-time (30-40 hours/week for at least 12 weeks) = 4 credits; part-time (15-20 hours/week for at least 12 weeks) = 2 credits. -
ENG ME 900: PhD Research
Participation in a research project under the direction of a faculty advisor leading to the preparation and defense of a PhD prospectus. -
ENG ME 925: Graduate Project
A practical mechanical design, analysis, fabrication, or production project. Written report required. -
ENG ME 951: Independent Study
Graduate students may study, under a faculty member's supervision, subjects not covered in a regularly offered course. Final report and/or written examination normally required. -
ENG ME 952: Mentored Proj
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ENG ME 954: MS Thesis
Participation in a research project under the direction of a faculty advisor leading to the preparation of an original MS thesis. For students pursuing an MS thesis to satisfy the practicum requirement for the MS degree. -
ENG ME 991: PhD Dissertation
Participation in a research project under the direction of a faculty advisor leading to the preparation and defense of an original PhD dissertation. -
ENG MS 306: Introduction to Materials Science
Structure and properties of solids; crystalline structure; defect structures; atom movement and diffusion; nucleation and growth; deformation; phase diagrams; strengthening mechanisms; heat treatment; ferrous/nonferrous alloys; ceramics; polymers; composites. Includes lab. Meets with ENGME306. Students may not receive credit for both. -
ENG MS 465: Materials Processing
The influence of manufacturing processes on structure and properties of materials. Manufacturing by liquid and solid state processing techniques, material removal processes and bonding and joining processes. Surface modification techniques for enhancing performance and product service life. Includes lab. Meets with ENGME465. Students may not receive credit for both. -
ENG MS 500: Special Topics in Materials Science and Engineering
Coverage of a specific topic in materials science and engineering. Subject varies from year to year and is generally from an area of current or emerging research. -
ENG MS 503: Kinetic Processes in Materials
Kinetics of mass transport, continuum and atomistic approaches, chemical diffusion; kinetics of chemical reactions, kinetics of adsorption and evaporation; nucleation and growth; solidification; spinodal decomposition; coarsening; martensitic transformations; order-disorder reactions; point defects and their relation to transport kinetics. Meets with ENGME503; students may not receive credit for both. -
ENG MS 504: Polymers and Soft Materials
An introduction to soft matter for students with background in materials science, chemistry, and physics. This course covers general aspects of structures, properties, and applications of soft materials such as polymers, colloids, liquid crystals, amphiphiles, gels, and biomaterials. Emphasis on chemistry and forces related to molecular self-assembly. Topics include forces, energies, kinetics in material synthesis, growth and transformation; methods for preparing synthetic materials; formation, assembly, phase behavior, and molecular ordering of synthetic soft materials; structure, function, and phase transition of natural materials such as nucleic acids, proteins, polysaccharides, and lipids; techniques for characterizing the structure, phase and dynamics of soft materials; application of soft materials in nanotechnology. Meets with ENG ME 504; students may not receive credit for both. -
ENG MS 505: Thermodynamics and Statistical Mechanics
The laws of thermodynamics; general formulation and applications to mechanical, electromagnetic and electromechanical systems; thermodynamics of solutions, phase diagrams; thermodynamics of interfaces, adsorption; defect equilibrium in crystals; statistical thermodynamics, including ensembles, gases, crystal lattices, and phase transitions. Same as ENGME505; students may not receive credit for both. -
ENG MS 507: Process Modeling and Control
An introduction to modeling and control as applied to industrial unit processes providing the basis for process development and improvement. Major themes include an integrated treatment of modeling multi-domain physical systems (electrical, mechanical, fluid, thermal), application of classical control techniques, and system design. Topics include modeling techniques, analysis of linear dynamics, control fundamentals in the time and frequency domain, and actuator selection and control structure design. Examples drawn from a variety of manufacturing processes and case studies. Meets with ENGME507. Students may not receive credit for both. -
ENG MS 508: Computational Methods in Materials Science
Introduction to computational materials science. Multi-scale simulation methods; electronic structure, atomistic, micro-structure, continuum, and mathematical analysis methods; rate processes and rare events. Materials defect theory; modeling of crystal defects, solid micro-structures, fluids, polymers, and bio-polymers. Materials scaling theory: phase transition, dimensionality, and localization. Perspectives on predictive materials design. Same as ENGME508; students may not receive credit for both. -
ENG MS 523: Mechanics of Biomaterials
Covers the chemical composition, physical structure, and mechanical behavior of engineering materials and the tissues they sometimes replace. Study of materials classes; materials selection; deformation of an elastic solid; yield and fracture; fundamentals of viscoelastic phenomena such as creep, stress relaxation, stress rupture, mechanical damping, impact; effects of chemical composition and structure on mechanical properties; methods of chemical property evaluation. Fracture and fatigue. Influences of plastics fabrication methods on mechanical properties. Emphasis on recent research techniques and results. Discussion of practical matters in medical device design including regulatory approvals, sterilization, packaging and quality control. Students will complete a semester-long design project. Same as ENG ME 523 and ENG MS 523; students can only receive credit for one of these courses. -
ENG MS 524: Skeletal Tissue Mechanics
The course is structured around classical topics in mechanics of materials and their application to study of the mechanical behavior of skeletal tissues, whole bones, bone-implant systems, and diarthroidal joints. Topics include: mechanical behavior of tissues, (anisotropy, viscoelasticity, fracture and fatigue) with emphasis on the role of the microstructure of these tissues; structural properties of whole bones and implants (composite and asymmetric bean theories); and mechanical function of joints (contact mechanics, lubrication, and wear). Emphasis is placed on using experimental data to test and to develop theoretical models, as well as on using the knowledge gained to address common health related problems related to aging, disease, and injury. Meets with ENGME524 and ENGBE524. Students may not receive credit for both. -
ENG MS 526: Simulation of Physical Processes
Modern simulation methods are covered for describing and analyzing the behavior of realistic nonlinear systems that occur in the engineering and science disciplines. By developing and applying such methods and tools, much deeper understanding, insight, and control of novel technologies can be gained, thereby often greatly aiding technology development, and sometimes providing the leverage to turn a novel technology into a practical reality. Advanced numerical methods are covered for attacking nonlinear partial differential equations. Key aspects of the finite element method. Extensive use is made of the modern computational tools Maple and Scientific Workplace. Examples including problems in micro- and nanoelectronics, bioengineering, material science, photonics, and physics are introduced and related to sensing instrumentation and control. Meets with ENGME526. Students may not receive credit for both.

