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Microelectronics Process Engineering: A Non-Traditional Approach to MS&E

Published online by Cambridge University Press:  15 March 2011

E. Allen
Affiliation:
Department of Chemical and Materials EngineeringSan Jose State UniversitySan Jose, CA 95192
S. Gleixner
Affiliation:
Department of Chemical and Materials EngineeringSan Jose State UniversitySan Jose, CA 95192
G. Young
Affiliation:
Department of Chemical and Materials EngineeringSan Jose State UniversitySan Jose, CA 95192
D. Parent
Affiliation:
Department of Electrical EngineeringSan Jose State UniversitySan Jose, CA 95192
Y. Dessouky
Affiliation:
Department of Industrial and Systems EngineeringSan Jose State UniversitySan Jose, CA 95192
L. Vanasupa
Affiliation:
Department of Materials EngineeringCalifornia Polytechnic State University, San Luis Obispo, California
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Abstract

Materials Science and Engineering straddles the fence between engineering and science. In order to produce more work-ready undergraduates, we offer a new interdisciplinary program to educate materials engineers with a particular emphasis on microelectronics-related manufacturing. The bachelor's level curriculum in Microelectronics Process Engineering (μProE)is interdisciplinary, drawing from materials, chemical, electrical and industrial engineering programs and tied together with courses, internships and projects which integrate thin film processing with manufacturing control methods. Our graduates are prepared for entry level engineering jobs that require knowledge and experience in microelectronics-type fabrication and statistics applications in manufacturing engineering. They also go on to graduate programs in materials science and engineering. The program objectives were defined using extensive input from industry and alumni. We market our program as part of workforce development for Silicon Valley and have won significant support from local industry as well as federal sources. We plan to offer a vertical slice of workforce development, from lower division engineering and community college activities to industry short courses. We also encourage all engineering majors to take electives in our program. All our course and program development efforts rely on clearly defined learning objectives.

Type
Research Article
Copyright
Copyright © Materials Research Society 2001

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References

REFERENCES

1. Allen, E. L. and Green, E. D.H., Procs. Frontiers in Education Conf., IEEE (1997).Google Scholar
2. Muscat, A.J., Allen, E.L., Green, E.D.H. and Vanasupa, L.S., J. Engr. Educ. 87, 413 (1998).Google Scholar
3. Allen, E. L. and Muscat, A. J., in Procs. 13th Biennial University/Government/Industry Microelectronics Symp., IEEE (1999).Google Scholar
4. National Science Foundation Award #DUE-9551520Google Scholar
5. National Science Foundation Award #DUE-9952707Google Scholar
6. Don Fowlkes, Masters Thesis, College of Engineering, San Jose State University, 2001.Google Scholar
7. Bloom, B., ed. Taxonomy of Educational Objectives in the Cognitive Domain, University of Chicago Press, 1955.Google Scholar