Solar sailing is a unique form of propulsion where a spacecraft gains momentum from incident photons. Since sails are not limited by reaction mass, they provide continual acceleration, reduced only by the lifetime of the lightweight film in the space environment and the distance to the Sun. Practical solar sails can expand the number of possible missions that are difficult by conventional means. The National Aeronautics and Space Administration’s Marshall Space Flight Center (MSFC) is concentrating research into the utilization of ultra lightweight materials for spacecraft propulsion. Solar sails are generally composed of a highly reflective metallic front layer, a thin polymeric substrate, and occasionally a highly emissive back surface. The Space Environmental Effects Team at MSFC is actively characterizing candidate sails to evaluate the thermo-optical and mechanical properties after exposure to electrons. This paper will discuss the preliminary results of this research.

1.
Evans, S. W., Ed., “Natural Environment Near the Sun/Earth-Moon L2 Liberation Point,” Next Generation Space Telescope Program, NASA Marshall Space Flight Center, MSFC, AL, http://sail.msfc.nasa.gov/nse/sgst.html
2.
Tsander, F. A., 1969, “From a Scientific Heritage,” Translation, pp. 1–92, NASA TT F-541, National Aeronautics and Space Administration, Washington, DC.
3.
Blagonravov, A. A., Editor, 1968, “K. E. Tsiolkovsky Selected Works,” Translation by G. Yankovsky, Mir Publishers, Moscow, USSR, pp. 140–163.
4.
Tsander, F. A., 1964, “The Use of Light Pressure for Flight in Interplanetary Space, Problems of Flight by Jet Propulsion,” L. K. Korneev, Ed., Israel Program for Scientific Translations, Jerusalem, Israel, pp. 303–321.
5.
McInnes, C. R., 1999, “Solar Sailing: Technology, Dynamics and Mission Applications,” Praxis Publishing, Chichester, UK, pp. 1–50.
6.
Clarke, A. C., 1990, “The Wind From the Sun,” A. C. Clarke, Ed., “Project Solar Sail,” Penguin Books, New York, pp. 9–31.
7.
Souza, D. M., 1994, “Space Sailing,” Lerner Publications Company, Minneapolis, MN, pp. 1–63.
8.
“NASA Marshall Space Flight Center Solar Wind,” NASA Marshall Space Flight Center, MSFC, AL, http://science.msfc.nasa.gov/ssl/pad/solar/sun_wind.htm/
9.
“Science News and Information About the Sun-Earth Space Environment,” http://www.spaceweather.com/
10.
Hollerman, W. A. et al., 2003, “Accelerator-Based PIXE and STIM Analysis of Candidate Solar Sail Materials,” Proceedings of the Seventeenth International Conference on the Application of Accelerators in Research and Industry, edited by J. Duggan and I. Morgan, American Institute of Physics, Denton, TX.
11.
“Kapton and Mylar Material Properties,” E. I. duPont de Nemours and Company, http://www.dupont.com/
12.
“LabVIEW and Related Data Acquisition Hardware,” National Instruments Corporation, Austin, TX, http://www.ni.com/
13.
Edwards, D., Hubbs, W., Stanaland, T., Hollerman, A., and Altstatt, R., 2002, “Characterization of Space Environmental Effects on Candidate Solar Sail Material,” Proceedings, 47th International Symposium on Optical Science and Technology, Seattle, WA.
14.
Halbleib, J. A., Kensek, R. P., Valdez, G. D., Seltzer, S. M., and Berger, M. J., 1992, “ITS Version 3.0: The Integrated Tiger Series of Coupled Electron/Photon Monte Carlo Transport Codes,” SAN91-1634, Sandia National Laboratories, Albuquerque, NM.
15.
Krane, K. S., 1988, “Introductory Nuclear Physics,” John Wiley and Sons Publishing, New York, NY, pp. 196–198.
16.
Cember, H., 1983, “Introduction to Health Physics,” 2nd ed., Pergamon Press Publications, New York, pp. 99–101.
17.
McCrum, N. G., Buckley, C. P., and Bucknall, C. B., 1988, “Principles of Polymer Engineering,” Oxford Science Publications, New York, NY, pp. 101–166.
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