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Course Criteria
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1.00 Credits
Handson experiences to reinforce fundamental materials engineering concepts. Crystal models, microscopy, hardness tests, strengthening, and heat treatment. Materials selection and design. Emphasis on technical written and oral communication skills. Safety awareness reinforced throughout the course. Elements of statistics and experimental design. 1 threehour laboratory. Prerequisite: MTE 207 (or ME 315).
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3.00 Credits
A comprehensive exploration of the field of mechanical metallurgy. Topics include the continuum description of stress and strain, the flow and fracture of metals from the defect mechanism point of view, the tests used for determining mechanical properties, and the fundamental/analytical techniques applied to the various metalworking processes used in industry. Labs will include demonstrations, plant trips, and problem solving. Relevant mathematical topics will be reviewed, 3 lectures/problemsolving, and 1 threehour laboratory. Prerequisites: MTE 207 (or ME 315); and MTE 317L (or ME 350L).
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3.00 Credits
A comprehensive exploration of electronic, thermal, magnetic and optical properties of materials. Relationships between structure and properties will be emphasized. The influence of processing on properties and subsequent applications will be highlighted. Labs will include development of experiments, and problem solving. 3 lectures and 1 threehour laboratory. Prerequisites: MTE 207, MTE 317L, PHY 133/133L.
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3.00 Credits
Macroscopic thermodynamics, the study of energy and its transformations as it applies to the field of materials. First and second law, property relationships, equilibrium, electrochemistry, solutions and mixing, phase rule and phase diagrams. Introduction to statistical thermodynamics will be included as it applies to the understanding of the macroscopic properties and behavior of materials. 3 lectures/ problemsolving. Prerequisite: MTE 207 (or ME 315).
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2.00 Credits
Introduction to the principles, methods and applications of joining as they apply to the metals, ceramics, plastics, and electronic industries. Included are fasteners, welding, brazing, soldering, adhesives, diffusion and ultrasonic bonding. Principles of mechanical, chemical, and physical phenomena related to surfaces and the mechanics of joints. The approach will be to unify the principles underlying diverse engineering technologies to the basic science of the joining processes. 2 lectures/problemsolving and 1 threehour laboratory. Prerequisites: MTE 207 (or ME 315); and MTE 317L (or ME 350L).
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3.00 Credits
Physical chemistry applied to materials engineering. Topics include: surfaces and interfaces; nucleation and growth theory; diffusional and nondiffusional transformations; precipitation from the solid solution, reaction kinetics, and introduction to nonequilibrium thermodynamics. 3 lectures/problemsolving. Prerequisites: MTE 207 or ME 315; CHE 302 or ME 301.
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12.00 Credits
Individual or group investigation, research, studies or surveys of selected problems. Total credit limited to 4 units, with a maximum of 2 units per quarter. Prerequisite: ENG 104 or equivalent.
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3.00 Credits
Fundamental principles of corrosion science, application of these principles to corrosion engineering problems and materials selection. Topics to be covered include: Thermodynamics and kinetics of metallic corrosion; corrosive/destructive environments; the different forms of corrosion and degradation, corrosion/degradation prevention; principles of materials selection. 3 lectures/problemsolving and 1 threehour laboratory. Prerequisites: CHE 303 or ME 302; MTE 207 or ME 315.
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4.00 Credits
Advanced concepts of electronic materials and their engineering applications. Free electron model, introduction to band theory, and Schrodinger wave equation, crystal bonding and lattice vibrations. Introduction to processing and materials selection for electronic applications. 4 lectures/problemsolving. Prerequisites: MTE 327 or ME 315; CHE 302 or ME 301.
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4.00 Credits
Basic principles underlying the structure and properties of crystalline solids. Metallic and covalent bonding theories; crystallography; solid solutions, intermetallic compounds and alloys. Crystal imperfections; elastic and plastic deformation. Ductile and brittle fracture, fatigue and creep. 4 lectures/problemsolving. Prerequisites: MTE 207 (or ME 315); CHE 302 (or ME 301).
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