Final Report (Appendix) - Cover Page.psd - interplanetary expeditions

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126. Shafirovich, E. Ya. and Goldshleger, U. I, “The Superheat Phenomenon in the Combustion of Magnesium Particles”, Combustion and Flame, Volume 88, 1992, pp425 – 432 127. Shafirovich, E. Ya. and Goldshleger, U. I., “Mars Multi-Sample Return Mission”, Journal of the British Interplanetary Society, Volume 48, 1995, pp315 – 319 128. Shafirovich, E. Ya. and Goldshleger, U. I., “Comparison of Potential Fuels for Martian Rockets Using CO2”, Journal of Propulsion and Power, Volume 13, Number 3, May – June 1997, pp395 – 397 129. Shafirovich, E. Ya. and Goldshleger, U. I., “Pulsating Combustion of Magnesium Particles in CO”, Combustion Science and Technology, Volume 135, 1998, pp241 – 254 130. Shirley, Donna L. and McCleese, Daniel J., “Mars Exploration Strategy : 1995 – 2020”, AIAA 96- 0333, 24 th Aerospace Sciences Meeting & Exhibit, January 15 – 18, 1996, Reno, NV 131. Smith, Lawrence A., Gupta N., Sass, Bruce M., Bubenik, Thomas A., Byrer, C., Bergman, P., “Engineering and Economic Assessment of Carbon Dioxide Sequestration in Saline Formations”, Journal of Energy and Environmental Research, Volume 2, February 2002, pp 5 – 22 132. Sparks, D. R., “Hybrid Rocket Propellant from Lunar Materials”, Acta Astronautica, Vol. 17, No. 10, pp 1093 – 1097, 1988 133. Sridhar, K. R., “Mars Sample Return Mission with ISSP”, Journal of the British Interplanetary Society, Volume 49, Number 11, November 1996, pp 435 - 440 134. Sridhar, K. R. and Vaniman, B. T., “Oxygen Production on Mars using Solid Oxide Electrolysis”, Solid State Ionics, Volume 93, 1997, pp321-328 135. Sridhar, K. R., Gottmann, M. and Baird, R. S., “2001 Mars In-Situ Oxygen Production Flight Demonstration”, 35 th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit, 20 – 23 June 1999, AIAA 99-2413 136. Sridhar, K. R., Finn, J. E. and Kliss, M. H., “In-Situ Resource Utilisation Technologies for Mars Life Support Systems”, Advanced Space Research, Volume 25, Number 2, 2000, pp249 – 255 137. Stancati, M.L., Niehoff, J. C., Wells, W. C., Feingold, H and Ash, L., “In Situ Propellant Production for Improved Sample Return Mission Performance”, AAS 79-177, pp909-921 138. Stancati, M. L., Niehoff, J. C., and Wells, W. C., and Ash, R. L., “In Situ Propellant Production : A New Potential for Round Trip Spacecraft”, AIAA Paper No. 79-0906, presented at the AIAA/NASA Conference on Advanced Technology for Future Space Systems, Hampton, VA, May 1979 139. Stancati, M. L., German, D. J., Jacobs M. K. and Neihoff, J. C., “Mars In-Situ Propellant Production : Needs and Technologies”, Science Applications International Corporation, unpublished [just the abstract] 140. Stefanescu, D. M., Grugel, R. N. and Curreri, P. A., “In Situ Resourc e Utilization for Processing of Metal Alloys on Lunar and Mars Bases”, Source Unknown 141. Sullivan, T. A., Linne, D., Bryant, L., and Kennedy, K., “In-Situ Produced Methane and Methane/Carbon Monoxide Mixtures for Return Propulsion Systems on Mars”, Journal of Propulsion and Power, Volume 11, 1056-1062, 1995 142. Tamura, K., Kohno, M. and Akiba, R., “A Feasibility Study of a Jet Pump for Powder Rockets”, Proceedings of the 11 th International Symposium for Space Technology and Science, June 30th – July 4 th 1975, pp117-122 143. TeGrotenhuis, W. E., Wegeng, R. S., Vanderwiel, D. P, Whyatt, G. A., Viswanathan, V. V., Schielke, K. P., Sanders, G. B. and Peters, T. A., “Microreactor System Design for NASA In Situ Propellant Production on Mars”, pp5, Source Unknown
144. Thunnissen, D., Rapp, D., Voorhees, C., Dawson, S. and Guernsey, C., “A 2007 Mars Sample Return Mission Utilizing In-Situ Propellant Production”, 37 th AIAA Aerospace Sciences Meeting and Exhibit, January 11 – 14, 1999 145. Tracadas, P. W., Smith, D. E., Zuber, M. T. and Lemoine, F. G., “The Density Structure of the Martian Thermosphere from MGS Drag Measurements during SPO”, Lunar and Planetary Science XXXI, pp2, Source Unknown 146. Wadel, Mary F., “Benefits of In-Situ Propellant Utilisation for a Mars Sample Return Mission”, AIAA 93-2244, AIAA/SAE/ASME/ASEE 29 th Joint Propulsion Conference and Exhibit, June 28-30, 1993/Monterey, CA 147. Wänke, H., Brückner, J., Dreibus, G., Reider, R. and Ryabchikov, I., “Chemical Composition of Rocks and Soils at the Pathfinder Site”, Composition and Origin of Cometary Materials, Kluwer Academic Publishers, Volume 96, pp319 – 332, 2001 148. Weaver, David B. and Duke, Michael B., “Mars Exploration Strategies : A Reference Program and Comparison of Alternative Architectures”, AIAA 93-4212 149. Weaver, W. L., “Mars Surface-to-Orbit Vehicles for Sample Return Missions”, Journal of Spacecraft, Volume 11, pp 426 – 428, 1974 150. Weaver, William L., “Mars Surface-to-Orbit Vehicles for Sample Return Missions”, Journal of Spacecraft, Volume 11, 1974, pp 426-8 151. Weaver, W. L., Darnell, W. L., Norton, H. N. and Jaffe, J. D., “Mars Sample Return through Parking Orbit”, Astronautics and Aeronautics, Volume 13, pp 42 – 51, 1975 152. Wickman, John H. and James, E., “Gelled Liquid Oxygen/Metal Powder Monopropellants”, AIAA 92- 3450, pp15 153. Wickman, John H., “Design of a LOX/Aluminum Lunar Propellant Rocket Engine”, AIAA 94-2842, 30 th AIAA/ASME/SAE/ASEE Joint Propulsion Conference, June 27 – 29, 1994, Indianapolis 154. Wickman, J. H., “In-Situ Mars Rocket and Jet Engines Burning Carbon Dioxide”, AIAA-99-2409 155. Williams, J. D., Coons, S. C. and Bruckner, A. P., “Design of a Water Vapor Adsorption Reactor for Martian In Situ Resource Utilisation”, Journal of the British Interplanetary Society, Volume 48, Number 8, August 1995, pp 347 - 354 156. Whitehead, J. C. and Guernsey, C. S., “Mars Ascent Propulsion on a Minimum Scale”, unpublished, pp8 157. Whitehead, J. C., “Mars Ascent Propulsion Options for Small Sample Return Vehicles”, AIAA 97- 2950, 1997 158. Yoshida, T. and Yuasa, S., “Effect of Water Vapour on Ignition and Combustion of Boron Lumps in an Oxygen Stream”, Proceedings of the Combustion Institute, Volume 28, 2000, pp2735-2741 159. Yuasa, S. and Takeno, T., “Ignition and Combustion of Magnesium-Aluminium Alloy Particle Clouds in a Hot Gas Stream”, Nineteenth Symposium (International) on Combustion, The Combustion Institute, 1982, pp741-748 160. Yuasa, S. and Isoda, H., “Ignition and Combustion of Metals in a Carbon Dioxide Stream”, 22 nd International Symposium on Combustion, The Combustion Institute, 1988, 1635 – 1641 161. Yuasa, S. and Isoda, H., “Carbon Dioxide Breathing Propulsion for a Mars Airplane”, AIAA-89-2863 162. Yuasa, S. and Isoda, H., “Ignition and Combustion of Small Boron Lumps in an Oxygen Stream”, Combustion and Flame, Volume 86, pp216-222, 1991
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Technology Requirements for Mars Sa
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Mineral Composition Cordierite Mg2A
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Mineral Composition Nesquehonite Mg
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Appendix B: European Gas Manufactur
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COUNTRY O2 H2 N2 CH4 CO2 COMPANY AD
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Appendix C: European Metal Producer
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COUNTRY Al Ti Mg Fe Si COMPANY ADDR
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Appendix D: PEP Outputs Carbon Diox
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DH DENS COMPOSITION CARBON DIOXIDE
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Carbon Dioxide (CO2) Chamber Pressu
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Liquid Oxygen (LOX) Chamber Pressur
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DH DENS COMPOSITION OXYGEN (LIQUID)
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DH DENS COMPOSITION CARBON MONOXIDE
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Page 78 and 79: DH DENS COMPOSITION OXYGEN (LIQUID)
Page 92 and 93: DH DENS COMPOSITION METHANE -1271 .
Page 106 and 107: ***SOLUTION AT 2.00 SECONDS*** ABLA
Page 108 and 109: NODE MATL NODE DEPTH TEMP (IN) (DEG
Page 110 and 111: 2 1 .0500 3800.0000 3 1 .1000 3725.
Page 112 and 113: 6 1 .2500 3491.7120 7 0 .3000 3337.
Page 114 and 115: 2. Chamber Conditions ***SOLUTION A
Page 116 and 117: NODE MATL NODE DEPTH TEMP (IN) (DEG
Page 118 and 119: 2 1 .0500 1747.1370 3 1 .1000 1641.
Page 120 and 121: 6 1 .2500 2034.9140 ***SOLUTION AT
Page 122 and 123: 18. Branstetter, J. Robert, Lord, A
Page 124 and 125: 54. Greeley, R. (Editor), “Scient
Page 126 and 127: 91. Meissinger, Hans F., Dawson, S.
Page 130: 163. Yuasa, S., Sogo, S., and Isoda
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