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Approach To An Interdisciplinary Bionanotechnology Education Program: International Network Perspective

Published online by Cambridge University Press:  01 February 2011

Ashok Vaseashta
Affiliation:
prof.vaseashta@marshall.edu, Marshall University, Physics and Physical Sciences, One John Marshall Drive, Huntington, WV, 25755-2570, United States, 304 696 2755, 304 696 2755
J. Irudayaraj
Affiliation:
josephi@ecn.purdue.edu, Purdue University, Agricultural & Biological Engineering, 225 S. University Street, West Lafayette, IN, 47907-2093, United States
S. Vaseashta
Affiliation:
sherri.vaseashta@marshall.edu, Marshall University, Nanomaterials Processing & Characterization Laboratories, One John Marshall Drive, Huntington, WV, 25755, United States
I. Stamatin
Affiliation:
istarom@polymer.fizica.unibuc.ro, University of Bucharest, Faculty of Physics, 3 Nano & Alternative Energy Sources Research Center, Bucharest-Magurele, N/A, N/A, Romania
A. Erdem
Affiliation:
arzum.erdem@ege.edu.tr, Ege University, Analytical Chemistry Department, 35100 Bornova, Izmir, N/A, N/A, Turkey
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Abstract

Materials in reduced dimensions demonstrate size dependence and may exhibit properties different from the bulk. Nanomaterials are a fundamentally and entirely new class of materials with remarkable electrical, optical, and mechanical properties, thus offering unique applications. With a 9.7% increase in FY 2004-05 investments and an expected worldwide labor force shortage, education and training has become a key component of the National Nanotechnology Initiative (NNI). The slow response by the academic community to develop nanotechnology curriculum is evidenced by the small number of Universities offering fundamental undergraduate level courses in nanoscience and nanotechnology. There is a strong need to develop coercive undergraduate curriculum to equip the future engineers, scientists, and researchers charged with commercializing nanotechnology applications. We are in the process of developing and implementing some core courses and laboratory modules, which can easily adapt to either a major or minor in nanotechnology, nano-biotechnology, or nanoscience programs. The course modules are being developed by a multi-disciplinary team consisting of faculty in Physics, Agricultural and Biological Engineering, Materials Engineering, and Molecular Biology at Universities in the US, Europe, and the Consortium of South East European Network on Nanoscience and Technology (COSENT). The joint effort specifically addresses a sector of nanobiotechnology emphasizing applications in agricultural and biological systems through hands-on modules and experimental kits. Selected course and laboratory modules are being developed to be affordable, flexible, accessible, and appealing to a diverse student population from across basics sciences, life sciences, agriculture, and engineering departments. Internet ready, multimedia intensive curriculum and assessment modules will include self-directed individualized learning modules as well as team-based components capitalizing on collaborative learning to address complex problems and tasks. The capital cost and site sensitivity of much of the equipment used within nanoscience courses often limits its distribution to large research centers, despite the need for it in many disperse educational programs. The creation of this seamless integration will promote and encourage an international exchange of students and ideas within interdisciplinary research. We will present our unique approach to delivery of education and training at all levels employing converging technologies to an international audience and receive feedback to enhance the effectiveness of the program to better educate the task force of tomorrow.

Type
Research Article
Copyright
Copyright © Materials Research Society 2006

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References

1. Vaseashta, , “Nanotechnology: Challenges of Convergence, Heterogeneity, and Hierarchical Integration,” Carbon Nanotubes, Ed. Popov, V.N. and Lambin, P.H., (Springer, 2006), pp. 229231.Google Scholar
2. Anderson, P.W., “More Is Different,” Science. 177, 393396 (1972).Google Scholar
3. Roco, M. C., “Converging Science and Technology at the Nanoscale: Opportunities for Education and Training,” Nature Biotechnology. 21, 12471249 (2003).Google Scholar
4. Vogel, V. and Campbell, C., “Education in Nanotechnology: Launching the first Ph. D. Program”, Int. J. Eng. Education. 18, 498 (2002).Google Scholar
5. Vaseashta, A., and Irudayaraj, J., Journal of Optoelectronics and Advanced Materials. 7, 35 (2005).Google Scholar