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Ultimate Properties of Polymer Chains

Published online by Cambridge University Press:  15 February 2011

W. Wade Adams ,
Ruth Pachter ,
Peter D. Haaland ,
Thomas R. Horn ,
Scott G. Wierschke  and
Robert L. Crane
W. Wade Adams
Affiliation:
Wright Laboratory, Materials Directorate, Wright-Patterson Air Force Base, Ohio 45433
Ruth Pachter
Affiliation:
This work was done while the author held a National Research Council Research Associateship
Peter D. Haaland
Affiliation:
Wright Laboratory, Materials Directorate, Wright-Patterson Air Force Base, Ohio 45433
Thomas R. Horn
Affiliation:
Wright Laboratory, Materials Directorate, Wright-Patterson Air Force Base, Ohio 45433
Scott G. Wierschke
Affiliation:
Department of Chemistry, U.S. Air Force Academy, Colorado 80840
Robert L. Crane
Affiliation:
Wright Laboratory, Materials Directorate, Wright-Patterson Air Force Base, Ohio 45433
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Abstract

New polymers with exceptional properties are needed for applications in high-performance structures, novel electrical, optical and electro-optical devices, and for multi-functional smart materials. Concurrently, new computational capabilities and methods for properties prediction and analysis have enabled the study of a variety of polymer chain architectures to examine the principles that govern their high-performance properties. By semi-empirical and ab initio computational methods, flexible, stiff-chain, rigid-rod, and biological structures could be analyzed. Single chain molecular stress-strain curves for axial tension and compression were calculated, and the strain dependence of the molecular modulus and vibrational frequencies were compared to measurements of molecular deformation, such as IR and Raman spectroscopy. However, of special interest is the distinctly different response of alpha-helical biopolymer chains to strain. Indeed, in this study we compare on a theoretical basis the ‘spring-like’ microscopic mechanical response of alpha-helical biopolymers having a reinforcing intra-molecular hydrogen bonding network to analogous synthetic extended chain polymers, especially poly(para-phenylene terephthalamide) (PPTA) [KEVLARTM]. The theoretical verification of the absence of compressive buckling in alpha-helical biopolymer chains rationalizes the molecular elasticity and resistance to ‘kinking’ of those strands, manifested by the prevalence in Nature for coiled coils. The understanding of the structure-tofunction relationship in biopolymers explaining the role of the alpha-helix in these systems as a requirement for superior compressive mechanical properties, may enable new guidance for the synthesis of motifs consistent with molecular frameworks optimized by Nature.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 305: Symposium I – High-Performance Polymers and Polymer Matrix Composites , 1993 , 39
Copyright
Copyright © Materials Research Society 1993

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References

[1] Allcock, H.R., Science, 255, 1106 (1992).Google Scholar
[2] Cis- and trans- PBI [poly(para-phenylene benzobisimidazole)] rigid rods were first synthesized in 1975 and reported by Kovar, R.F. and Arnold, F.E., J. Poly. Sci., Poly. Chem. Ed., 14, 2807 (1976), while cis- and trans- PBO rigid rods by T.E. Helminiak, F.E. Arnold, and C.L. Benner, Polymer Preprints, ACS Poly. Div. 16, 659 (1975). Cis- PBO [poly(para-phenylene benzobisoxazole)] is under study at present by Dow Chemical and others for use as a high performance fiber or film, while trans- PBO is difficult to synthesize in high molecular weights due to quinone formation in the para-OH monomer. Cis- and trans- PBZT [poly(para-phenylene benzobisthiazole)] rigid rods, which were first synthesized in 1978 (J.F. Wolfe, B H. Loo, and F.E. Arnold, Polymer Preprints, ACS Poly. Div., 19, 1 (1978)), are the sulfur analogs to cis- and trans- PBO. Both materials have been studied structurally, and are also of interest in the area of nonlinear optics. Model compounds were examined by X-ray crystallography (M.W. Wellman, W.W. Adams, R.A. Wolff, D.S. Dudis, D.R. Wiff, and A.V. Fratini, Macromolecules, 14, 935 (1981)), revealing that cis- PBZT appears as a bowed, less extended structure than trans- PBZT.Google Scholar
[3] Reviews of ordered polymers have recently appeared by Kumar, S., International Encyclopedia of Composites, 4, 5174 (1991) and by J.F. Wolfe, Encyclopedia of Polymer Science and Engineering, 11, 601 (1988). Also, a symposium was directed to that subject at a Materials Research Society Meeting, edited by W.W. Adams, R.K. Eby, and D.E. McLemore, The Materials Science and Engineering of Rigid rod Polymers, Materials Research Society Symposium Proceedings, 134(1989).Google Scholar
[4] McGarry, F.J. and Moalli, J.E., Polymer, 32, 1816 (1991); T.D. Dang, L.S. Tan, K.H. Wei, H.H. Chuah, and F.E. Arnold, Proc. Polym. Mat. Sci. Eng. (ACS) 60, 424 (1989); M. Dotrong and R.C. Evers, Proc. Polym. Mat. Sci. Eng. (ACS), 507 (1989); H.H. Chuah, T.T. Tsai, C. Wang, and F.E. Arnold, Proc. Polym. Mat. Sci. Eng. (ACS), 517 (1989); D.L. Vezie, Ph.D. Dissertation, Massachusetts Institute of Technology, 1993..CrossRefGoogle Scholar
[5] Pachter, R., Cooper, T.M., Natarajan, L.V., Obermeier, K.A., Crane, R.L., and Adams, W.W., Biopolymers 32, 1129 (1992)Google Scholar
[6] Klunzinger, P.E., Eby, R.K., Polymer, 34, 2431 (1993).Google Scholar
[7] Rutledge, G.C., Suter, U.W., Polymer, 32, 179 (1991).CrossRefGoogle Scholar
[8] Sorensen, R.A., Liau, W.B., Boyd, R.H., Macromolecules, 21, 194 (1988).Google Scholar
[9] Tashiro, K., Kobayashi, M., and Tadokoro, H., Macromolecules, 11, 908 (1978).CrossRefGoogle Scholar
[10] Wierschke, S.G., Shoemaker, J.R., Pachter, R., Haaland, P.D., and Adams, W.W., Polymer, 33, 357 (1992).Google Scholar
[11] Shoemaker, J.R., Horn, T.R., Haaland, P.D., Pachter, R., Adams, W.W., Polymer, 33, 351 (1992).Google Scholar
[12] Shoemaker, J. R., M.Sc. Thesis, Air Force Institute of Technology, 1991.Google Scholar
[13] Horn, T.R., Haaland, P.D., Pachter, R., Adams, W.W., Polymer, in pressGoogle Scholar
[14] Haaland, P.D., Pachter, R., and Adams, W.W., Polymer, Polymer, in pressGoogle Scholar
[15] Haaland, P. D., Pachter, R., Pachter, M., Adams, W.W., Chemical Phys. Lett., 199, 379 (1992).Google Scholar
[16] Warrick, H.M. and Spudich, J.A., Ann. Rev. Cell Biol. 3, 379 (1987).Google Scholar
[17] Byers, T.J. and Branton, D., Proc. Nat. Acad. Sci. 82,6153 (1985).Google Scholar
[18] Marchesi, V.T., Ann. Rev. Cell Biol. 1, 531 (1985).CrossRefGoogle Scholar
[19] Kaplan, D.L., Lombardi, S.J., Muller, W.S., and Fossey, S.A., “Silks: Chemistry, Properties, and Genetics-Biomaterials: Novel Materials from Biological Sources”, Macmillan Press (1991); F. Vollrath, Scientific American, 70, March (1992); F. Vollrath and D.T. Edmonds, Nature, 340, 305 (1989).Google Scholar
[20] Mahoney, D.V., Vezie, D.L., Eby, R.K., Adams, W.W. & Kaplan, D.L., “Silks,” ACS Sym. Series, ed Kaplan, D.L., Adams, W.W., Viney, C. & Farmer, B.L., In press 1993.Google Scholar
[21] McGarry, F.J. and Moalli, J.E., Polymer, 32, 1816 (1991); S.J. LeTeresa, R.S. Porter, and R.J. Farris, J. Mater. Sci., 23 1886 (1988).Google Scholar
[22] Stewart, J.J.P. in MOPAC (Version 5.0), Quantum Chemistry Program Exchange &455.Google Scholar
[23] Similar to the HtIckel treatment of cyclic bonding in simple cases developed by Stewart, J.J.P., New Polym. Materials, 1, 53 (1987).Google Scholar
[24] Klei, H.E., Stewart, J.J.P., Int. J. Quant. Chem., Quant. Chem. Symp., 20, 529 (1986).Google Scholar
[25] The invention by duPont of the spinning of liquid crystalline acid solutions of the stiffchain of PPTA opened the field of extremely high performance organic fibers (Kwolek, S., U. S. Patent No. 3 600 356 1971).Google Scholar
[26] Adams, W.W. and Eby, R.K., MRS Bulletin, 23 (1987).Google Scholar
[27] Allen, S. R., Polymer 29, 1091 (1988); K. Tashiro, M. Kobayashi, and H. Tadokoro, Macromolecules, 10, 413 (1977); R. J. Gaymans, J. Tijssen, S. Harkema, and A. Bantjes, Polymer, 17, 517 (1976).Google Scholar
[28] Karasawa, N., Dasgupta, S., and Goddard, W. A., J. Phys. Chem., 95, 2260 (1991).Google Scholar
[29] Rutledge, G.C., Suter, U.W., Papaspyrides, C.D., Macromolecules, 24, 1934 (1991).Google Scholar
[30] Tanner, D., Fitzgerald, J.A., Phillips, B.R., Adv. Mater., No. 5, 151 (1989).Google Scholar
[31] Chang, C., Hsu, S.L., Macromolecules, 23, 1484 (1990), and by R.J. Young, private communication.Google Scholar
[32] Perkins, P.G., Stewart, J.J.P., J. Chem. Soc. Faraday Trans. II, 76, 520 (1980).CrossRefGoogle Scholar
[33] CHARMm (Chemistry at HARvard Macromolecular mechanics) developed by Brooks, B.R., Bruccoleri, R.E., Olafson, B.D., States, D.J., Swaminathan, S., Karplus, M., J. Comp. Chem. 4, 187 (1983), coded in Quanta: Release 3.0, Polygen Corporation, 1990.Google Scholar
[34] Wegner, G., private communication, estimates the modulus as ca. 30 GPa.Google Scholar
[35] Bustamante, C., Vesenka, J., Polymer Preprints, ACS Poly. Div. 33,743 (1992).Google Scholar
[36] Magat, E.E., Philos. Trans. R. Soc., (London), A, 294, 463 (1980).Google Scholar
[37] Lenhert, P.G. and Adams, W.W., Air Force Wright Laboratory Technical Report WRDCTR-90-4070, 1990.Google Scholar
[38] Fielding-Russell, G.S., Textile Research Journal, 41, 861 (1971).Google Scholar
[39] Tashiro, K., Kobayashi, M., and Tadokoro, H., Macromolecules, 10, 143 (1977).Google Scholar