Polymer-Single Wall Carbon Nanotube Composites for Potential Spacecraft Applications

Cheol Park; Zoubeida Ounaies; Kent A. Watson; Kristin Pawlowski; Sharon E. Lowther; John W. Connell; Emilie J. Siochi; Joycelyn S. Harrison; Terry L. St. Clair

doi:10.1557/PROC-706-Z3.30.1

Abstract

Polymer-single wall carbon nanotube (SWNT) composite films were prepared and characterized as part of an effort to develop polymeric materials with improved combinations of properties for potential use on future spacecraft. Next generation spacecraft will require ultra-lightweight materials that possess specific and unique combinations of properties such as radiation and atomic oxygen resistance, low solar absorptivity, high thermal emissitivity, electrical conductivity, tear resistance, ability to be folded and seamed, and good mechanical properties. The objective of this work is to incorporate sufficient electrical conductivity into space durable polyimides to mitigate static charge build-up. The challenge is to obtain this level of conductivity (10-8 S/cm) without degrading other properties of importance, particularly optical transparency. Several different approaches were attempted to fully disperse the SWNTs into the polymer matrix. These included high shear mixing, sonication, and synthesizing the polymers in the presence of pre-dispersed SWNTs. Acceptable levels of conductivity were obtained at loading levels less than one tenth weight percent SWNT without significantly sacrificing optical properties. Characterization of the nanocomposite films and the effect of SWNT concentration and dispersion on the conductivity, solar absorptivity, thermal emissivity, mechanical and thermal properties were discussed. Fibers and non-woven porous mats of SWNT reinforced polymer nanocomposite were produced using electrospinning.

References

1. Iijima, S., Nature 354, 56 (1991).Google Scholar

2. Ajayan, P. M., Chem. Rev. 99 1787, (1999).Google Scholar

3. Chen, J., Hamon, M. A., Hu, H., Chen, Y., Rao, A. M., Eklund, P. C., and Haddon, R. C., Science, 282 95, (1998).Google Scholar

4. Mickelson, E. T. et al., Chem. Phys. Lett. 296 188 (1998).Google Scholar

5. Bahr, J. L. and Tour, J., Chem. Mater. 13 3823 (2001).Google Scholar

6. Fan, J., Wan, M., Zhu, D., Chang, B., Pan, Z., and Xie, S., J. Appl. Polym. Sci. 74 2605 (1999).Google Scholar

7. Park, C. et al., NASA Invention disclosure, submitted.Google Scholar

8. Clair, A. K. St. and Clair, T. L. St., and Slemp, W. S., Proceeding of the 2^nd International Conference on Polyimides, ed. Weber, W. and Gupta, M., (Soceity of Plastics Engineers, 1987) pp.16–36.Google Scholar

9. , Park et al, manuscript in prep.Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Breuer, O. and Sundararaj, Uttandaraman 2004. Big returns from small fibers: A review of polymer/carbon nanotube composites. Polymer Composites, Vol. 25, Issue. 6, p. 630.

Mathew, G. Hong, J.P. Rhee, J.M. Lee, H.S. and Nah, C. 2005. Preparation and characterization of properties of electrospun poly(butylene terephthalate) nanofibers filled with carbon nanotubes. Polymer Testing, Vol. 24, Issue. 6, p. 712.

Adhikari, A R Huang, M Bakhru, H Chipara, M Ryu, C Y and Ajayan, P M 2006. Thermal property of regioregular poly(3-hexylthiophene)/nanotube composites using modified single-walled carbon nanotubes via ion irradiation. Nanotechnology, Vol. 17, Issue. 24, p. 5947.

Kalamkarov, A.L. Georgiades, A.V. Rokkam, S.K. Veedu, V.P. and Ghasemi-Nejhad, M.N. 2006. Analytical and numerical techniques to predict carbon nanotubes properties. International Journal of Solids and Structures, Vol. 43, Issue. 22-23, p. 6832.

MacDonald, Rebecca A. Voge, Christopher M. Kariolis, Mihalis and Stegemann, Jan P. 2008. Carbon nanotubes increase the electrical conductivity of fibroblast-seeded collagen hydrogels. Acta Biomaterialia, Vol. 4, Issue. 6, p. 1583.

Guadagno, Liberata Vertuccio, Luigi Sorrentino, Andrea Raimondo, Marialuigia Naddeo, Carlo Vittoria, Vittoria Iannuzzo, Generoso Calvi, Erika and Russo, Salvatore 2009. Mechanical and barrier properties of epoxy resin filled with multi-walled carbon nanotubes. Carbon, Vol. 47, Issue. 10, p. 2419.

Seidel, Gary Boehringer, Kelli and Lagoudas, Dimitris 2009. Computational Micromechanics Analysis of the Effects of Interphase Regions and Bundle Packing on the Effective Electrical Properties of Carbon Nanotube-Polymer Nanocomposites.

Heeder, N. Shukla, A. Chalivendra, V. Yang, S. and Park, K. 2011. Dynamic Behavior of Materials, Volume 1. p. 361.

Seidel, G.D. and Puydupin-Jamin, A.-S. 2011. Analysis of clustering, interphase region, and orientation effects on the electrical conductivity of carbon nanotube–polymer nanocomposites via computational micromechanics. Mechanics of Materials, Vol. 43, Issue. 12, p. 755.

Heeder, N. Shukla, A. Chalivendra, V. and Yang, S. 2012. Sensitivity and dynamic electrical response of CNT-reinforced nanocomposites. Journal of Materials Science, Vol. 47, Issue. 8, p. 3808.

Li, Jin-Jin and Zhu, Ka-Di 2013. All-optical mass sensing with coupled mechanical resonator systems. Physics Reports, Vol. 525, Issue. 3, p. 223.

Prabhu, Y. T. Venkateswara Rao, K. Siva Kumari, B. and Pavani, Tambur 2015. Decoration of magnesium oxide nanoparticles on O-MWCNTs and its antibacterial studies. Rendiconti Lincei, Vol. 26, Issue. 3, p. 263.

Fadel, Tarek R. and Meador, Michael A. 2016. Nanotechnology: Delivering on the Promise Volume 1. Vol. 1220, Issue. , p. 23.

Guo, Wanchun Jia, Yin Tian, Kesong Xu, Zhaopeng Jiao, Jiao Li, Ruifei Wu, Yuehao Cao, Ling and Wang, Haiyan 2016. UV-Triggered Self-Healing of a Single Robust SiO2 Microcapsule Based on Cationic Polymerization for Potential Application in Aerospace Coatings. ACS Applied Materials & Interfaces, Vol. 8, Issue. 32, p. 21046.

Clausi, Marialaura Santonicola, M. Gabriella Schirone, Luigi and Laurenzi, Susanna 2017. Analysis of ultraviolet exposure effects on the surface properties of epoxy/graphene nanocomposite films on Mylar substrate. Acta Astronautica, Vol. 134, Issue. , p. 307.

Samir, Z. Boukheir, S. Belhimria, R. Achour, M. E. and Costa, L. C. 2019. Electrical Transport Properties of Carbon Nanotube/Polyester Polymer Composites. Journal of Superconductivity and Novel Magnetism, Vol. 32, Issue. 2, p. 185.

Ortiz-Morales, A. Ortiz-López, J. Leal-Acevedo, B. and Gómez-Aguilar, R. 2019. Thermoluminescence of single wall carbon nanotubes synthesized by hydrogen-arc-discharge method. Applied Radiation and Isotopes, Vol. 145, Issue. , p. 32.

Ebrahimi, Nesa Hosseini, Mohammad Amin and Malekie, Shahryar 2020. Preliminary study of linearity response of γ-irradiated graphene oxide as a novel dosimeter using the Raman spectroscopy. Bulletin of Materials Science, Vol. 43, Issue. 1,

Mählich, Daniel Eberhardt, Oliver and Wallmersperger, Thomas 2021. Numerical simulation of the mechanical behavior of a carbon nanotube bundle. Acta Mechanica, Vol. 232, Issue. 2, p. 483.

Bijanu, Abhijit Arya, Rahul Agrawal, Varsha Tomar, Akshay Singh Gowri, V. Sorna Sanghi, Sunil Kumar Mishra, Deepti and Salammal, Shabi Thankaraj 2021. Metal-polymer composites for radiation protection: a review. Journal of Polymer Research, Vol. 28, Issue. 10,

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Polymer-Single Wall Carbon Nanotube Composites for Potential Spacecraft Applications

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This article has been cited by the following publications. This list is generated based on data provided by Crossref.

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