22 6 2 0 0 2 11 QUATERNARY SCIENCES Vol. 22, No. 6 November, 2002 3 (, 100012 ;, 550002 ;, 550002), () ;, 66-3, - 3 ;; 1,,,10 %; 40 Ar, 40 Ar 40 K [1 ] 1-6 1 [ 2] Table 1 The escape velocity of some planets and satellites in the solar system [2 ] Πkm s - 1 Πkm s - 1 11. 2 4. 3 10. 4-6 2. 5 5. 0 2. 4, [2 ] 1, - 6,,,, 3 : 38 E2mail :ylzou @bao. ac. cn (: KZCX2-115) (: KGCX2-406) 2002-07 - 29,2002-09 - 02
534 2 0 0 2, - 6,,, ; 1Π80,1Π50, 1Π6,, [1 ],,, 130 150, - 180-160,, k c = 1Π( k ) 1Π2 (1) 2 [3 ],, 35 2 [ 3] Table 2 The average temperature on the lunar surface [3 ] ΠK 40 220 254 256 255 255 2, (), K. Wat2 son 1) 1961, 1. 6,,40 50K,,,,, Apollo Luna,,, 1994,, 234 200km 1) [4,5 ]
6 : 535,,,, 1998,, [6,7 ],, 0. 3 % 1 %, 10cm [6,7 ] [5,6 ], 10 000 50 000 km 2, 5 000 20 000 km 2, 650 km 2, 1 850 km 2,, 66 200, [4,5 ] : 1) ; 2) FeO ( FeO + H 2 = Fe + H 2 O) ; 3),,,, 3 3, [1,8 ], ( ),, X, [9 ], 30 50nm,,, ( 3), - 3 3 [1 ] Table 3 The concentrations of rare gases in the lunar regolith [1 ] Πcm 3 g - 1 4 HeΠ10-2 20 NeΠ10-4 36 ArΠ10-4 84 KrΠ10-8 132 XeΠ10-8 Apollo - 11 11 25 20 31 3. 3 4. 1 16 38 2. 1 10 52. 4 108. 1 Apollo - 12 4 38 7 61 1. 2 3. 1 4 20 1. 1 2. 6 17. 3 124. 7 Apollo - 14 5 9 9 16 2. 4 4. 4 9 24 1. 4 4. 6 26. 8 58. 0 Apollo - 15 4 10 7 22 0. 9 4. 1 4. 4 24 0. 6 3. 3 16. 9 63. 4 Apollo - 16 0. 6 5. 1 2. 4 13 1. 3 6. 0 4. 5 34 1 6. 5 9. 8 64. 6 Apollo - 17 ( ) Apollo - 17 ( ) 12 29 5. 9 16 14 45 12 28 1. 6 6. 2 2. 5 4. 9 3. 7 16 10 18 1. 3 2. 4 1. 8 2. 9 32. 6 98. 6 32. 2 69. 8 Luna - 16 18 34 5. 4 22 8. 5 87. 9 Luna - 20 3. 81 10. 1 2. 88 10. 9 2. 25 29. 94,,, 3 He, 20 Ne, 21 Ne, 22 Ne,
536 2 0 0 2 38 Ar; U,Th K 4 He, 40 Ar ; Kr,Xe Xe, 4,, 4 [ 1] Table 4 Comparison of the ratio of rare gases isotope abundances in the fine grains of the lunar regolith with that of the solar wind and Earth s atmosphere [1 ] 4 HeΠ 3 He 4 HeΠ 20 Ne 20 NeΠ 22 Ne 22 NeΠ 21 Ne 20 NeΠ 36 Ar 2 300 2 800 96 18 12. 4 12. 8 31 1. 2 2 350 120 570 70 13. 7 0. 03 30 4 28 9 7 10 5 0. 3 9. 8 0. 08 34. 5 1. 0 0. 5 [5,8 ],,,, ;,,,,, 0. 2 m,, 0. 1 1cm 3 Πg ( ),10 19 10 20 Πcm 3, - 3, - 3, : 1) ; 2) -,, - 3,,, - 3-3, - 3 3 4 ngπg, 3 He,, 3 He Apollo Luna ( 5m, 10m), 3 He 100 500 4,,, [9,10 ], [1 ], ( 1) ( 1)
6 : 537 1 [9 ] 67455,62231,12063 12070 Fig. 1 The reflectance of the lunar surface materials [9 ], ( 50 %),,,, 1 ( ), ( 5) 5 [ 3] Table 5 Normal reflectance values of the lunar near and far side [3 ] 0. 06 0. 09 0. 07 0. 11 0. 20 0. 15 0. 07 0. 10 0. 09 0. 22 5,,, ;36 38 38 36 [1 ],, [11,12 ],, : 1) 1 5nT ; 2),
538 2 0 0 2 10nT( 0. 78),, : 1) 36 38, ; 2) ( 10kmΠs),,,, 5 [11 ],,,, ; [11,12 ], ( 10GPa),,700, 400 6, : (1),, (2) 66 200 (3),, ;,, - 3 100 500 (4), (5),,, 1.. :,1988. 93 145 2... :,1998. 47 96 3 Preter E. The Lunar Base Handbook. New York : The McGraw Hill Companies, Inc., 1999. 140 149 4 Feldman W C, Maurice S, Binder A B et al. Fluxes of fast and epithermal neutrons from Lunar Prospector. Science,1998, 281 (4) :1 496 1 500 5 Grant Heiken, David Vaniman, Bevan M French. Lunar Sourcebook : A User s Guide to the Moon. New York : Cambridge Uni2 versity Press,1991. 287 305,342 351 6 Feldman W C, Barraclough B L, Maurice S et al. Major compositional units of the moon : Lunar Prospector thermal and fast neutrons. Science, 1998, 281(4) :1 489 1 493 7 Feldman W C, Lawrence D J, Elphic R C et al. Chemical information content of lunar thermal and epithermal neutrons. Jour2 nal of Geophysical Research, 2000, 105( E8) : 20 347 20 363 8.. :,1977. 41 53,172 187 9 Piters M, Englert A J. Remote Geochemistry Analysis : Elemental and Mineralogical Composition. New York : Cambridge Uni2 versity Press,1993. 309 366
6 : 539 10 Pieters C M, Fischer E M, Rode O et al. Optical effects of space weathering : The role of the finest fraction. Journal of Geo2 physical Research, 1993, 98 ( E11) : 20 817 20 824 11 Lin R P, Mitchell D L, Curtis D W et al. Lunar surface magnetic fields and their interaction with the solar wind : Results from Lunar Prospector. Science, 1998, 281(4) : 1 480 1 484 12 Hood L, Huang Z. Formation of magnetic anomalies antipodal to lunar impact basins : Two2dimensional model caiculations. Journal of Geophysical Research, 1991, 96 :9 837 9 846 L UNAR SURFACE ENVIRONMENTAL CHARACTERISTICS Zou Yongliao Ouyang Ziyuan Xu Lin Liu Jianjun Xu Tao ( National Astronomical Observatories, Chinese Academy of Sciences, Beijing 100012 ; Institute of Geochemistry, Chinese Academy of Sciences, Guiyang 550002 ; State Key Laboratory of Environmental Geochemistry, Institute of Geochemistry, Chinese Academy of Sciences, Guiyang 550002) Abstract Based on the exploration data and previous studies, the authors suggest that small volume and mass of the moon, the short distance from the sun ( i e. high surface temperature) result in the very tenuous and thin lunar atmosphere, demonstrate that there exits ice2water on shadow area of the lu2 nar polar region and calculate out 6. 6 Ga tons of ice. By comparing the composition of rare gas elements in the lunar regolith and in the solar wind, the authors analyze the physical, chemical and isotopic effects of the solar radiation on the lunar sur2 face materials, the distributions and contents of the 3 He in the lunar regolith, point out that the con2 tent of 3 He relates with grain size, the mineral components, structures and elemental compositions of the lunar soil, and evaluate the exploration values of 3 He. The lunar surface materials govern the lunar reflectance. Based on the spectrum characteristics of the mare basalts, highland plagioclases and their mineral components which both of them are the main rocks of the lunar surface materials, the authors analyze the different reflectance of the lunar near side and far side. Not only is the lunar magnetic field the important part of the lunar environment but also great significance for studying on the lunar interior structures. The moon has regional scale distribution magnetic field which may result from great impact processes. Key words lunar surface environment, atmosphere, rare gas,reflectance, magnetic field