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Implications of Emerging Micro and Nanotechnology (2002)
Air Force Science and Technology Board (AFSTB)

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. "3. Major Areas of Opportunity." Implications of Emerging Micro and Nanotechnology. Washington, DC: The National Academies Press, 2002.

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Implications of Emerging Micro- and Nanotechnologies

189. Martin, D.H. 2000. Communication Satellites, 4th Edition. Reston, Va.: American Institute of Aeronautics and Astronautics.

190. Iannazzo, S. 1993. A survey of the present status of vacuum microelectronics. Solid State Electronics 36(3): 301–320.

191. Jensen, K.L., R.H. Abrams, and R.K. Parker. 1998. Field emitter array development for high frequency applications. Journal of Vacuum Science Technology B 16(2): 749–753.

192. Spindt, C.A., C.E. Holland, P.R. Schwoebel, and I. Brodie. 1998. Field emitter array development for microwave applications: II. Journal of Vacuum Science & Technology B 16(2): 758– 761.

193. Jo, S.H., K.W. Jung, Y.J. Kim, S.H. Ahn, J.H. Kang, H.S. Han, B.G. Lee, J.C. Cha, S.J. Lee, S.Y. Park, C.G. Lee, J.H. You, N.S. Lee, and J.M. Kim. 2001. Carbon nanotube cathode with low operating voltage. Pp. 31–32 in IVMC 2000: Proceedings of the 14th International Vacuum Microelectronics Conference. New York, N.Y.: IEEE.

194. Spindt, C.A. 1992. Microfabricated field-emission and field-ionization sources. Surface Science 266(1–3 ): 145–154.

195. Kwon, S.J., Y.H. Shin, D.M. Aslam, and J.D. Lee. 1998. Field emission properties of the polycrystalline diamond film prepared by microwave-assisted plasma chemical vapor deposition . Journal of Vacuum Science & Technology B 16(2): 712–715.

196. Fursey, G.N., L.A. Shirochin, and L.M. Baskin. 1997. Field-emission processes from a liquid-metal surface. Journal of Vacuum Science & Technology B 15(2): 410–421.

197. Taylor, G. 1964. Disintegration of water drops in electric field. Proceedings of the Royal Society of London Series A—Mathematical and Physical Sciences 280(138): 383–397.

198. Mitterauer, J. 1991. Miniaturized liquid-metal ion sources (MILMIS). IEEE Transactions on Plasma Science 19(5): 790–799.

199. Mitterauer, J. 1992. Prospects of liquid metal ion thrusters for electric propulsion. Paper 105 in Proceedings of the AIDAA/AIAA/DGLR/JSASS 22nd International Electric Propulsion Conference, Volume 2. Pisa, Italy: Centrospazio.

200. Spindt, C.A. 1992. Microfabricated field-emission and field-ionization sources. Surface Science 266(1–3 ): 145–154.

201. Hoyt, R.P. 2000. Design and Simulation of a Tether Boost Facility for LEO to GTO Transport, AIAA paper 2000-3866. Reston, Va.: American Institute of Aeronautics and Astronautics.

202. Hoyt, R.P., and C. Uphoff. 1999. Cislunar Tether Transport System, AIAA paper 99-2690. Reston, Va.: American Institute of Aeronautics and Astronautics.

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