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Course Criteria
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4.00 Credits
Lecture, two hours; laboratory, eight hours. Synthesis and characterization of organic and inorganic materials including polymers and oxides. Techniques include electron and scanning probe microscopy, gel permeation chromatography, x-ray diffraction, porosimetry, and thermal analysis. Prerequisites: ENGR54 or Chemistry 130A-B or 131A-B. Same as Chemistry 156. (Design units: 0).
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3.00 Credits
Covers the principles of environmental degradation and corrosion including environmental effects, electrochemical aspects, eight forms of corrosion, corrosion testing, oxidation at elevated temperatures, susceptibilities of various engineering materials, and prevention of environmental degradation. Prerequisites: ENGR54 and CBEMS50L. (Design units: 2)
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3.00 Credits
Principles and practical guidelines of automated materials testing. Computer fundamentals, programming languages, data acquisition and control hardware, interfacint techniques, programming strategies, data analysis, data storage, safeguard procedures. Prerequisite: consent of instructor. Concurrent with MSE263. (Design units: 1)
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4.00 Credits
Material characterization using x-ray diffraction and scanning electron microscopy (SEM). Topics include x-ray diffraction and analysis; SEM imaging and microanalysis. Prerequisite: ENGR54. (Design units: 1)
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3.00 Credits
Thermodynamics and kinetics of phase transformations, phase diagrams, diffusional and diffusionless transformations. Prerequisites: ENGR54; CBEMS40B or CBEMS45C or MAE91. (Design units: 0)
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3.00 Credits
Covers the properties of nanoscale materials and aspects of current research on next-generation electronic devices. Topics include nanofabrication, characterization of nanostructure materials, and device concepts that take the advantage of quantum mechanical phenomena on the nanoscale. Prerequisites: ENGR54 and Physics 7D. Concurrent with MSE266. (Design units: 0)
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3.00 Credits
Multidisciplinary case study approach to environmentally sustainable manufacturing with a focus on electronic products. Engineering, economic, public policy, and industrial ecology aspects. Design, manufacture, policy, and environmental impact reviewed as a function of the entire life-cycle of the materials from extraction through disposal or recycling. Prerequisite: senior standing or consent of instructor. Concurrent with MSE267. (Design units: 0)
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4.00 Credits
Covers the electronic, optical, and dielectric properties of crystalline and amorphous materials to provide a foundation of the underlying physical principles governing the properties of existing and emerging electronic and photonic materials. Prerequisites: Physics 7D and 7E, Mathematics 2J and 3D. (Design units: 1)
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3.00 Credits
Covers materials, processes, and principles involved in manufacturing of microelectronics and photonics after the silicon has been fabricated. Considerations of electronic, optical, thermal mechanical, and reliability properties of the materials are viewed in the context of current microelectronics manufacturing processes. Prerequisites: ENGR54, Chemistry 1C, Mathematics 2J, and Physics 7A-B-D-E. Concurrent with MSE272. (Design units: 1)
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3.00 Credits
Introduction to the semiconductor device packaging and assembly processes. Electrical, thermal, optical, and mechanical aspects of package design and reliability. Special topics on optoelectronics packaging are covered. Prerequisite: CBEMS40A or CBEMS45B or consent of instructor. (Design units: 1)
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