Chapter 2: Energy at the Lunar Surface - Lunar and Planetary Institute

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62 REFERENCES Jennison, R. C., McDonnell, J. A. M. and Rogers, I., 1967. The Ariel I1 micrometeorite penetration measurements. Proc. Roy. Soc. Lon., A., 300: 251-269. Keays, R. R., Ganapathy, R., Laul, J. C., Anders, E., Herzog, G. F. and Jeffery, D. M., 1970. Trace elements and radioactivity in lunar rocks: Implications for meteorite infall solar wind flux and formation conditions of moon. Science, 16 7 : 490-493. Kerridge, J. F ., 1970. Micrometeorite environment at the earth's orbit. Nature, 228: 616-619. Kerridge, J. F. and Vedder, J. F., 1972. Accretionary processes in the early solar system: An experimental approach. Science, 1 77: 161-162. Kovach, R. L., Watkins, J. S. and Talwani, P., 1972. Active seismic experiment. In: Apollo 16 Preliminary Science Report. NASA SP-3 15, 10-1 to 10-14. Kuiper, G, P., 1954. On the origin of the lunar surface features. Proc. Natl. Acad. Sci. U. S., 40: 1096. Kuiper, G. P., Strom, R. G. and LePoole, R. S., 1966. Interpretation of the Ranger records. J. P. L. Tech., Rep. 32-800, 35-248. Larimer, J. W. and Anders, E., 1967. Chemical fractions in meteorites - 11. Abundance patterns and their interpretation. Geochim. Cosmochim. Acta, 31: 1239-1270. Larimer, J. W. and Anders, E., 1970. Chemical fractions in meteorites - 111. Major element fractions in chondrites. Geochim. Cosmochim. Acta, 34: 367-387. Latham, G. V., Ewing, M., Press, F., and Sutton, G., 1969. The Apollo passive seismic experiment. Science, 165: 241-25 1. Latham, G. V., Ewing, M., Press, F., Sutton, G., Dorman, J., Nakamura, Y., Toksoz, N., Lammlein, D. and Duennebier, F., 1972. Passive seismic experiment, In: Apollo 16 Preliminary Sci. Rept., NASA SP-3 15, 9-1 to 9-29. Laul, J. C., Morgan, J. W., Ganapathy, R., and Anders E., 1971. Meteoritic material in lunar samples: Characterization from trace elements. Proc. Second Lunar Sci. Conf., Suppl. 2, Geochim. Cosmochim. Acta, 2: 1139-1 158. Lindbald, B. A., 1967. Luminosity function of sporadic meteors and extrapolation of the influx rate to micrometeorite region. In: Proceedings of a Symposium on Meteor Orbits and Dust. NASA SP-135, 171-180. Lindsay, J. F., 1972. Development of soil on the lunar surface. Jour. Sediment. Petrology, 42: 876-888. Lindsay, J. F. and Srnka, L. J., 1975. Galactic dust lanes and lunar soil. Nature, 157:776-778, Lindsay, J. F., Criswell, D. R., Criswell, T. L. and Criswell, B. S., 1975. Sound producing dune and beach sands. Geol. Soc. Amer. Bull. (in press). Lovell, A. C. B., 1954. Meteor Astronomy. Claredon Press, Oxford, London, 463 pp. Mandeville, J. C., and J. F. Vedder, 1971. Microcraters formed in glass by low density projectiles. Earth Planet. Sci. Lett., 11 : 297-306. Marcus, A. H., 1970. Comparison of equilibrium size distributions for lunar craters. Jour. Geophys. Res., 75: 4977-4984. Mason, B. H., 1962. Meteorites. Wiley, N.Y., 274 pp. Mason, B. H., 1971. Handbook of Elemental Abundances in Meteorites. Gordon and Breach, N.Y., 555 pp. McCoy, J. E. and Criswell, D. R., 1974. Evidence for a high altitude distribution of lunar dust. Proc. Fifth Lunar Sci. Conf., Suppl. 5, Geochim. Cosmochim. Acta, 3: 2991-3005. McCrosky, R. E. and Posen, A., 1961. Orbital elements of photographic meteors. Smithson. Contrib. Astrophys., 4: 15-84. McDonnell, J. A. M., 1970. Review in situ measurements of cosmic dust particles in space. Paper presented at 13th COSPA R Meeting, Leningrad. McDonnell, J. A. M. and Ashworth, D. G., 1972. Erosion phenomena on the lunar surface and meteorites. In Space Research XZZ, Akademie-Verlag, Berlin, 333-347. McDonnell, J. A. M., Ashworth, D. G., Flavill, R. P. and Jennison, R. C ., 1974a. Simulated microscale erosion on the lunar surface by hypervelocity impact, solar wind sputtering, and thermal cycling. Proc. Third Lunar Sci. Conf., Suppl. 3, Geochim Cosmochim. Acta, 3: 2755-2765.
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Page 1 and 2: CHAPTER 2 Energy at the Lunar Surfa
Page 3 and 4: DISTRIBUTION OF METEOROIDS Heliocen
Page 5 and 6: MEASURING THE METEOROID FLUX Measur
Page 7 and 8: MEASURING THE METEOROID FLUX suffic
Page 9 and 10: MASS-FREQUENCY DISTRIBUTION observa
Page 11 and 12: MASS-FREQUENCY DISTRIBUTION experim
Page 13 and 14: PHYSICAL PROPERTIES Escape Velociti
Page 15 and 16: PHYSICAL PROPERTIES he ratio a/b is
Page 17 and 18: PHYSICAL PROPERTIES r Meteorites I
Page 19 and 20: PHYSICAL PROPERTIES 37 requires pro
Page 21 and 22: HISTORY OF METEOROID FLUX History o
Page 23 and 24: METEOROID ENERGY Solar Flare Track
Page 25 and 26: SOLAR ENERGY 43 radiant energy flux
Page 27 and 28: GRAVITATIONAL ENERGY Fig. 2.16. Enl
Page 29 and 30: GRAVITATIONAL ENERGY Fig. 2.19. Bou
Page 31 and 32: GRAVITATIONAL ENERGY similarly the
Page 33 and 34: GRAVITATIONAL ENERGY Fig. 2.24. Soi
Page 35 and 36: GRAVITATIONAL ENERGY of seismic eve
Page 37 and 38: INTERNAL ENERGY 55 rate proportiona
Page 39 and 40: OTHER ENERGY SOURCES Fig. 2.28. A g
Page 41 and 42: CONCLUDING REMARKS \ Apollo Orbit I
Page 43: REFERENCES N. H and Ferry, G. W., 1

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