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Advanced Power Sources for Space Missions (1989)

Chapter: References

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Suggested Citation:"References." National Research Council. 1989. Advanced Power Sources for Space Missions. Washington, DC: The National Academies Press. doi: 10.17226/1320.
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Page 101
Suggested Citation:"References." National Research Council. 1989. Advanced Power Sources for Space Missions. Washington, DC: The National Academies Press. doi: 10.17226/1320.
×
Page 102
Suggested Citation:"References." National Research Council. 1989. Advanced Power Sources for Space Missions. Washington, DC: The National Academies Press. doi: 10.17226/1320.
×
Page 103

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References Billman, Fred. 1987. High Purity Aluminum Conductors. Electric Generator Developers Conference. (Alexandria, Virginia, January 21-22, 1987.) U.S. Army Belvoir RD&E Center Report AD-B112-729. Brown, William C. 1987. LEO to GEO Transportation System Combining Electric Propulsion with Beamed Microwave Power from Earth. Proceed- ings, AAS Goddard Memorial Symposium (NASA Goddard Space Flight Center, March 18-19, 1987~. Buckman, R. W., Jr., and R. R. Begley. 1969. Development of High-Strength Tantalum Base Alloys. Pp. 19-37 in Recent Aduanecs in Refractory Alloys for Space Power Syatcrru. NASA report SP-245. June. Buden, David. 1981. The acceptability of reactors in space. Report LA-8724- MS, Los Alamos National Laboratory (UC-33~. April. Colladay, Raymond S., and Edward A. Gabris. 1988. Presentation to Space Nuclear Power Systems Symposium. Albuquerque, New Mexico. January. Cooper, R., and J. Horak. 1984. In Proceedings of the Symposium on Refrac- tory Alloy Technology for Space Nuclear Power Applications (Oak Ridge, Tennessee, August 1~11, 1983), R. H. Cooper, Jr. and E. E. Hoffman, eds. Report CONF-8308130 (also, Report DE 84-001745~. January. Cropp, Louis. 1988. Sandia National Laboratories, IEG Field Support Team, personal communication. DeVan, J. H., and E. L. Long. 1975. Evaluation of T-lll Forced-Convection Loop Tested with Lithium at 1370° C. NASA report CR-134745. (Also published as Oak Ridge National Laboratory report ORNL TM-4775.) DeVan, J. H., J. R. DiStefano, and E. E. Hoffman. 1984. Compatability of Refractory Alloys with Space Reactor System Coolants and Working Fluids. Pp. 34-85 in Refractory Alloy Technology for Space Nuclear Power Applications, R. H. Cooper, Jr., and E. E. Hoffman, eds., DOE CONF-8301B130. 101

102 REFERENCES Eckels, Phillip. 1987. High Purity Aluminum. Electric Generator Developers Conference (Alexandria, Virginia, January 21-22, 1987~. U.S. Army Belvoir RD&E Center Report AD-B112-729. El-Genk, M. S., A. G. Parlos, J. M. McGhee, S. Lapin, D. Buden, and J. Mims. 1987. Pellet Bed Reactor Design for Space Power. Proceedings of 22nd Intersociety Energy Conversion Engineering Conference (Philadelphia, Au- gust 10-14, 1987~. American Institute of Aeronautics and Astronautics, Washington, D.C. English, Robert E. 1978. Alternative Power-Generating Systems. Conference on Future Orbital Power Systems Technology Requirements. NASA CP-2058. English, Robert E. 1987. Speculations on Future Opportunities to Evolve Bray- ton Power Plants Aboard the Space Station. Proceedings, 4th Symposium on Space Nuclear Power Systems, Albuquerque, New Mexico. January. Gas Turbine World. 1987. Handbook. 10:2-6. Gregorwich, W. S. 1987. Microwave Power Beaming from Earth-to-Space. Lockheed Research Laboratories, Palo Alto, California. Hoffert, M. I., B. Heilweil, G. Miller, W. Ziegler, and M. Kadiramangalam. 1987. Earth-to-Satellite Microwave Beams: A Non-Nuclear Approach to SDI Space Power. Department of Applied Science, New York University. Johnson, Colonel Joseph R. 1988. Testimony on Space Nuclear Reactor Power Systems, presented to the U.S. House of Representatives Committee on Science, Space, and Technology, March 16. Johnson, Nicholas L. 1986. Nuclear Power Supplies in Orbit. Space Policy, pp. 227-228. August. Johnstone, John A. 1988. Argonne National Laboratory, personal communica- tion. Klopp, William D., Robert H. Titran, and Keith D. Sheffler. 1980. Long- Term Creep Behavior of the Tantalum Alloy Astar 811C. NASA TP 1691. September. Kulcinski, G. L., and H. H. Schmitt. 1987. The Moon: An Abundant Source of Clean and Safe E`usion Fuel for the 21st Century. UWFDM-730, Fusion Technology Institute, University of Wisconsin, Madison. August. Lundberg, Lynn B. 1985. Refractory metals in space nuclear power. Journal of Metals, April:44-47. Mankins, J., J. Olivieri, and A. Hepenstal. 1987. Preliminary Survey of 21st Century Civil Mission Applications of Space Nuclear Power. JPL D-3547. Pasadena, California: Jet Propulsion Laboratory. March. Materials Research Society Conference. 1987. Georgia Institute of Technology. December. Murphy, G. B., S. D. Shawhan, and J. S. Pickett. 1983. "Perturbations to the plasma environment induced by the Orbiter's maneuvering thrusters, American Institute of Aeronautics and Astronautics (AIAA) Paper 83-2599, New York and Washington. October. NASA Internal Study. 1988. National Research Council. 1983. Committee on Advanced Nuclear Systems, "Advanced Nuclear Systems for Portable Power in Spaced Washington, D.C.: National Academy Press. National Research Council. 1988. Report of a study by the Committee on High- Temperature Materials for Advanced Technological Applications. Wash- ington, D.C.: National Academy Press.

REFERENCES 103 Pickett, J. S., et al. 1985. "Effects of chemical releases by the STS 3 Orbiter on the ionosphere," Journal of Geophysical Research, 90: 3487-3497. Ride, Sally K. 1987 Leadership and America's Future in Space. A report to the Administrator of NASA. Washington, D.C.: NASA. August. Rohwein, G. J., and W. J. Sarjeant. 1983. Critical Issues in Electrical Energy Storage and Transfer. Applied Physics Communications, 3:160210. Rosenblum, L., D. R. England, Jr., R. W. Hall, T. A. Moss, and C. Scheuer- mann. 1966. Potassium Rankine System Materials Technology. Pp. 169-199 in Proceedings, Space Power Sy~tenu Aduar~ced Technology Cor~fcrcnce. NASA report SP-131. Sarjeant, W. J. 1985. Briefing to the Defense Technology Study Team on Space Power Technology, Arlington, Virginia. June. Seaton, Michael K. 1985. A summary of the state of the art of nuclear safety of space nuclear reactors. Air Force Weapons Laboratory Report AFW~ TR-84-144, Dayton, Ohio. September. Shawhan, S. D., and G. B. Murphy. 1983. "Plasma diagnostics package assessment of the STS-3 Orbiter environment and systems for science, AIAA Paper 83-(1253, New York and Washington, January. Space Power Architecture System (SPAS) studies. 1988. Technical evaluations by the Field Support Team of the SDIO Power Program Office's Indepen- dent Evaluation Group of draft final reports by three contractors: General Electric, Martin Marietta, and TRW. Stephens, Joseph R., Donald W. Petrasek, and Robert H. Titran. 1988. Refractory Metal Alloys and Composites for Space Power Systems. NASA report TM 100946. Strategic Defense Initiative Organization (SDIO). 1986. SDI Survivability Tech- nology Hardening Goal. WPD-~004: Space Science Passive Survivability Technology FY87. October. Symposium on Space Nuclear Power Systems. 1988 (and previous years). Uni- versity of New Mexico. Proceedings, Mohamed El-Genk, ed. Albuquerque, New Mexico. USAF/DOE Evaluation Panel for Small Space Reactor Systems. 1988. Space Reactor Power Systems for 5 to 40 Kilowatts. Air Force Space Technology Center and U.S. Department of Energy. March.

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"Star Wars"—as the Strategic Defense Initiative (SDI) is dubbed—will require reliable sources of immense amounts of energy to power such advanced weapons as lasers and particle beams. Are such power sources available? This study says no, not yet—and points the way toward the kind of energy research and development that is needed to power SDI.

Advanced Power Sources for Space Missions presents a comprehensive and objective view of SDI's unprecedented power requirements and the opportunities we have to meet them in a cost-effective manner.

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