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Deaf and Hard of Hearing Undergraduate Interns Investigate Smart Polymeric Materials

Published online by Cambridge University Press:  31 January 2011

Peggy Cebe
Affiliation:
peggy.cebe@tufts.edu, Tufts University, Physics and Astronomy, Medford, United States
Daniel Cherdack
Affiliation:
daniel.cherdack@tufts.edu, Tufts University, Physics and Astronomy, Medford, United States
Robert Guertin
Affiliation:
robert.guertin@tufts.edu, Tufts University, Physics and Astronomy, Medford, United States
Terry Haas
Affiliation:
thaas@tufts.edu, Tufts University, Chemistry, Medford, United States
Wenwen Huang
Affiliation:
wenwen.huang@tufts.edu, Tufts University, Physics and Astronomy, Medford, United States
B. Seyhan Ince-Gunduz
Affiliation:
seyhan.ince@tufts.edu, Tufts University, Physics and Astronomy, Medford, United States
Roger Tobin
Affiliation:
roger.tobin@tufts.edu, Tufts University, Physics and Astronomy, Medford, United States
Regina Valluzzi
Affiliation:
rvalluzzi@alum.mit.edu, Tufts University, Physics and Astronomy, Medford, United States
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Abstract

Smart Materials are those which can undergo a reversible property change in response to an external influence. An important polymeric Smart Material is poly(vinylidene fluoride), or PVF2, which is piezoelectric. The structure of PVF2 determines which crystal phases will be electrically active. Recent research has shown that the electrically active beta phase of PVF2 grows preferentially in nanocomposites of PVF2 mixed with organically modified silicates (OMS) ‘1-4’. These nanocomposite Smart Materials offer a new processing strategy for PVF2 piezo-films. Using PVF2 nanocomposites as the research focal point, a summer internship program was developed for deaf and hard of hearing (DHH) undergraduate students [5,6]. This paper describes the program and presents research results achieved by the interns. It is written from the perspective of the Principal Investigator, Cebe, on behalf of all the co-authors.

Type
Research Article
Copyright
Copyright © Materials Research Society 2010

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References

1 Priya, L., Jog, J. P., J Polym Sci: Part B: Polym Phys, 89, 2036 (2003).Google Scholar
2 Priya, L., Jog, J. P., J Polym Sci, Part B: Polym Phys, 40, 1682 (2002).Google Scholar
3 Buckley, J., Cebe, P., Cherdack, D., Crawford, J., Ince, B. S., Jenkins, M., Pan, J., Reveley, M., Washington, N., Wolchover, N., Polymer, 47, 2411 (2006).Google Scholar
4 Ramasundaram, S., Yoon, S., Kim, K. J., Park, C., J Polym Sci, Part B: Polym Phys 46 2173 (2008).Google Scholar
5 Cebe, P., Cherdack, D., Guertin, R., Haas, T., Ince, B. S., Valluzzi, R., J Materials Education, 28(1), 151158 (2006).Google Scholar
6 Cebe, P., “A Team Approach: Using BEST Principles in an Internship Program for Deaf and Hard of Hearing Undergraduates.” Broadening Participation in Undergraduate Research. Eds., Boyd, M. and Wesemann, J. (Council on Undergraduate Research: Washington DC 2008, 2009) Section III, 215218.Google Scholar
7http://www.chemistry.org/portal/a/c/s/1/acsdisplay.html?DOC=membership\index.html The American Chemical Society lists 158,422 members for 2005, with 25% female members. Self-identified ACS members with a disability (of any type, not just deaf or hard of hearing) numbered 339, or 0.21% of members.Google Scholar
8http://www.nsf.gov/statistics/wmpd/listtables.htm National Science Foundation in Table B-10 gives the number of undergraduates in all Engineering Disciplines for 2002 at 421,178. Black undergraduates comprised 6.28%; females comprised 18.5%.Google Scholar
9 Ince-Gunduz, B. S., Alpern, R., Amare, D., Crawford, J., Dolan, B., Jones, S., Kobylarz, R., Reveley, M., Cebe, P., Polymer, in review (2010).Google Scholar
10 Huang, W., Edenzon, K., Fernandez, L., Razmpour, S., Woodburn, J., and Cebe, P.. J. Applied Polym. Sci., 115(6), 32383248 (2009).Google Scholar
11 Lovinger, A. J., “Poly(vinylidene fluoride).” Developments in Crystalline Polymers-1. Editor, Bassett, D. C. (Applied Science Publishers, London, 1982).Google Scholar
12 Lovinger, A. J., Science, 220, 1115 (1983)Google Scholar
13 Nakamura, S., Sasaki, T., Funamoto, J., Matsuzaki, K., Makromol Chem, 176, 3471 (1975).Google Scholar
14 Mancarella, L., Martuscelli, E., Polymer, 18, 1240 (1977).Google Scholar
15 Kawai, H., Jpn J Appl Phys, 8(7), 1975 (1969).Google Scholar
16 Welch, G. J., Miller, R. L., J Polym Sci Polym Phys Ed, 14, 1683 (1976).Google Scholar
17 Bachmann, M., Lando, J. B., Macromolecules, 14, 40 (1981).Google Scholar
18 Lando, J. B., Olf, H. G., Peterlin, A., J Polym Sci A-1, 4, 941 (1966).Google Scholar
19 Lovinger, A. J., Macromolecules, 14, 322 (1981).Google Scholar
20 Hasegawa, R., Takahashi, Y., Chatani, Y., Tadokoro, H., Polym J, 3, 600 (1972).Google Scholar
21 Kobayashi, M., Tashiro, K., Tadokoro, H., Macromolecules, 8, 158 (1975).Google Scholar
22 Yang, D., Chen, Y., J Mater Sci Lett, 6, 599 (1987).Google Scholar
23 Bachmann, M. A., Gordon, W. L., J Appl Phys, 50, 6106 (1979).Google Scholar
24 Kressler, J., Schafer, R., Thomann, R., Appl Spectr, 52, 1269 (1998).Google Scholar