參考文獻 |
Alexeev, I. I., Belenkaya, E. S., Slavin, J. A., Korth, H., Anderson, B. J., Baker, D. N., Boardsen, S. A., Johnson, C. L., Purucker, M. E., Sarantos, M., and Solomon, S. C. (2010). Mercury’s magnetospheric magnetic field after the first two MESSENGER flybys. Icarus, 209, 23–39.
Anderson, B. J., Acun ̃a, M. H., Korth, H., Purucker, M. E., Johnson, C. L., Slavin, J. A., Solomon, S. C., and McNutt, R. L. (2008). The structure of Mercury’s magnetic field from MESSENGER’s first flyby. Science, 321, 82–85.
Bagdonat, T. (2004). Hybrid simulation of weak comets. Ph.D. thesis Technische Uni- versit ̈at Braunschweig.
Bagdonat, T., and Motschmann, U. (2002). From a weak to a strong comet−3d global hybrid simulation studies. Earth, Moon and Planets, 90, 305–321.
Benkhoff, J., and Schulz, R. (2006). BepiColombo-mpo scientific aspects and system update. In Advances in Geosciences (pp. 51–62). World Scientific Publishing Co. Pte. Ltd, Singapore, Hackensack and London volume 3.
Benna, M., Anderson, B. J., Baker, D. N., Boardsen, S. A., Gloeckler, G., Gold, R. E., Ho, G. C., Killen, R. M., Korth, H., Krimigis, S. M., Purucker, M. E., McNutt, R. L., Raines, J. M., McClintock, W. E., Sarantos, M., Slavin, J. A., Solomon, S. C., and Zurbuchen, T. H. (2010). Modeling of the magnetosphere of Mercury at the time of the first MESSENGER flyby. Icarus, 209, 3–10.
Borin, P., Bruno, M., Cremonese, G., and Marzari, F. (2010). Estimate of the neutral atoms’ contribution to the Mercury exosphere caused by a new flux of micromete- oroids. Astronomy and Astrophysics, 517, A89.
Broadfoot, A. L., Kumar, S., Belton, M. J. S., and McElroy, M. B. (1974). Mercury’s atmosphere from Mariner 10: preliminary results. Science, 185, 166–169.
Broadfoot, A. L., Shemansky, D. E., and Kumar, S. (1976). Mariner 10 - Mercury atmosphere. Geophysical Research Letters, 3, 577–580.
Burger, M. H., Killen, R. M., Vervack, R. J., Bradley, E. T., McClintock, W. E., Saran- tos, M., Benna, M., and Mouawad, N. (2010). Monte Carlo modeling of sodium in Mercury’s exosphere during the first two MESSENGER flybys. Icarus, 209, 63–74.
Cheng, A. F., Johnson, R. E., Krimigis, S. M., and Lanzerotti, L. J. (1987). Magneto- sphere, exosphere, and surface of Mercury. Icarus, 71, 430–440.
Christensen, U. R. (2006). A deep dynamo generating Mercury’s magnetic field. Nature, 444, 1056–1058.
Cintala, M. J. (1992). Impact-induced thermal effects in the lunar and mercurian re- goliths. Journal of Geophysical Research, 97, 947–973.
Delcourt, D. C., Grimald, S., Leblanc, F., Berthelier, J.-J., Milillo, A., Mura, A., Orsini, S., and Moore, T. E. (2003). A quantitative model of the planetary Na+ contribution to Mercury’s magnetosphere. Annales Geophysicae, 21, 1723–1736.
Domingue, D. L., Koehn, P. L., Killen, R. M., Sprague, A. L., Sarantos, M., Cheng, A. F., Bradley, E. T., and McClintock, W. E. (2007). Mercury’s atmosphere: a surface-bounded exosphere. Space Science Reviews, 131, 161–186.
Farmer, A. J., and Goldreich, P. (2007). How much oxygen is too much? constraining Saturn’s ring atmosphere. Icarus, 188, 108–119.
Ferrari, C., Galdemard, P., Lagage, P. O., Pantin, E., and Quoirin, C. (2005). Imag- ing Saturn’s rings with camiras: thermal inertia of B and C rings. Astronomy and Astrophysics, 441, 379–389.
Fowles, G. R., and Cassiday, G. L. (1998). Analytical Mechanics. (Sixth ed.). Harcourt College Publisher.
Fulle, M., Leblanc, F., Harrison, R. A., Davis, C. J., Eyles, C. J., Halain, J. P., Howard, R. A., Bockel ́ee-Morvan, D., Gremonese, G., and Scarmato, T. (2007). Discovery of the atomic iron tail of comet McNaught using the heliospheric imager on STEREO. Astrophysical Journal, 661, L93–L96.
Gerald, C. F., and Wheatley, P. O. (2004). Applied Numerical Analysis. (Seventh ed.). Pearson International Edition.
Glassmeier, K.-H. (2000). Currents in Mercury’s magnetosphere. In Magnetospheric Current Systems (pp. 371–380). AGU Geophysical Monograph volume 118.
Gombosi, T. I., Dezeeuw, D. L., Groth, C. P. T., Hansen, K. C., Kabin, K., and Powell, K. G. (2000). MHD simulations of current systems in planetary magneto- spheres:Mercury and Saturn. In Magnetospheric Current Systems (p. 363). AGU Geophysical Monograph volume 118.
Gubbins, D. (1997). Speculations on the origin of the magnetic field of Mercury. Icarus, 30, 186–191.
Hodges, R. R. (1973). Helium and hydrogen in the lunar atmosphere. Journal of Geophysical Research, 78, 8055–8064.
Huebner, W. F., Keady, J. J., and Lyon, S. P. (1992). Solar photo rates for planetary atmospheres and atmospheric pollutants. Astrophysics and Space Science, 195, 1–294.
Hunten, D. M., Shemansky, D. E., and Morgan, T. H. (1988). The Mercury atmosphere. In F. Vilas, C. R. Chapman, and M. S. Matthews (Eds.), Mercury (pp. 562–612). Tucson, AZ, University of Arizona Press.
Ip, W.-H. (1986a). Cassini instruments related to interaction between magnetosphere and surfaces. In N. Longdon (Ed.), The Solid Bodies of the Outer Solar System (p. 179). Proceedings of a conference held at Vulcano, Italy, 9-13 September, 1985.
Ip, W.-H. (1986b). The sodium exosphere and magnetosphere of Mercury. Geophysical Research Letters, 13, 423–426.
Ip, W.-H. (1987). Dynamics of electrons and heavy ions in Mercury’s magnetosphere. Icarus, 71, 441–447.
Ip, W.-H. (1990). On solar radiation-driven surface transport of sodium atoms on Mer- cury. Astrophysical Journal, 356, 675–681.
Ip, W.-H. (1993a). Mercury and the moon, atmospheres. In S. P. Maran (Ed.), The Astronomy and Astrophysics Encyclopedia (pp. 418–420). Van Nostrand Reinhold, New York, and Cambridge University Press, Cambridge, Melbourne, Sydney.
Ip, W.-H. (1993b). On the surface sputtering effects of magnetospheric charged particles at Mercury. Astrophysical Journal, 418, 451–456.
Ip, W.-H. (1997). Time-variable phenomena in the magnetosphere and exosphere of Mercury. Advances in Space Research, 19, 1615.
Ip, W.-H., and Kopp, A. (2002a). MHD simulations of the solar wind interaction with Mercury. Journal of Geophysical Research, 107, 1348.
Ip, W.-H., and Kopp, A. (2002b). Resistive MHD simulations of Ganymede’s magneto- sphere 2. Birkeland currents and particle energetics. Journal of Geophysical Research, 107, SMP 41–1.
Ip, W.-H., and Wang, Y.-C. (2010). A comparison of the exospheres of Mercury and the Moon. Advances in Geosciences, 19, 1–8.
Janhunen, P., and Kallio, E. (2004). Surface conductivity of Mercury provides current closure and may affect magnetospheric symmetry. Annales Geophysicae, 22, 1829– 1837.
Johnson, R. E., and Baragiola, R. (1991). Lunar surface - sputtering and secondary ion mass spectrometry. Geophysical Research Letters, 18, 2169–2172.
Johnson, R. E., Luhmann, J. G., Tokar, R. L., Bouhram, M., Berthelier, J. J., Sittler, E. C., Cooper, J. F., Hill, T. W., Smith, H. T., Michael, M., Liu, M., Crary, F. J., and Young, D. T. (2006). Production, ionization and redistribution of o2 in Saturn’s ring atmosphere. Icarus, 180, 393–402.
Kabin, K., Gombosi, T. I., Dezeeuw, D. L., and Powell, K. G. (2000). Interaction of Mercury with the solar wind. Icarus, 143, 397–406.
Kallio, E., and Janhunen, P. (2003). Modeling the solar wind interaction with Mercury by a quasi-neutral hybrid model. Annales Geophysicae, 21, 2133–2145.
Kameda, S., Yoshikawa, I., Kagitani, M., and Okano, S. (2009). Interplanetary dust dis- tribution and temporal variability of Mercury’s atmospheric Na. Geophysical Research Letters, 36, L15201.
Keller, H. U., and Thomas, G. E. (1975). A cometary hydrogen model-comparison with OGO-5 measurements of comet Bennett (1970II). Astronomy and Astrophysics, 39, 7–19.
Killen, R. M., and Ip, W.-H. (1999). The surface-bounded atmospheres of Mercury and the Moon. Reviews of Geophysics, 37, 361–406.
Killen, R. M., Potter, A. E., Fitzsimmons, A., and Morgan, T. H. (1999). Sodium D2 line profiles: clues to the temperature structure of Mercury’s exosphere. Planetary and Space Science, 47, 1449–1458.
Killen, R. M., Potter, A. E., Reiff, P., Sarantos, M., Jackson, B. V., Hick, P., and Giles, B. (2001). Evidence for space weather at Mercury. Journal of Geophysical Research, 106, 20509–20526.
Killen, R. M., Sarantos, M., Potter, A. E., and Reiff, P. (2004). Source rates and ion recycling rates for Na and K in Mercury’s atmosphere. Icarus, 171, 1–19.
Killen, R. M., Shemansky, D. E., and Mouawad, N. (2009). Expected emission from Mercury’s exospheric species, and their ultraviolet-visible signatures. Astrophysical Journal Supplement Series, 181, 351–359.
Kopp, A., and Ip, W.-H. (2002). Resistive MHD simulations of Ganymede’s magne- tosphere 1. time variabilities of the magnetic field topology. Journal of Geophysical Research, 107, SMP 41–1.
Leblanc, F. (2006). Earth ground-based observations of Mercury exosphere- magnetosphere-surface relations. In Advances in Geosciences (pp. 5–15). World Sci- entific Publishing Co. Pte. Ltd, Singapore, Hackensack and London volume 3.
Leblanc, F., and Johnson, R. E. (2003). Mercury’s sodium exosphere. Icarus, 164, 261–281.
Leblanc, F., Luhmann, J. G., Johnson, R. E., and Liu, M. (2003). Solar energetic particle event at mercury. Planetary and Space Science, 51, 339–352.
Liu, Y., Richardson, J. D., and Belcher, J. W. (2005). A statistical study of the properties of interplanetary coronal mass ejections from 0.3 to 5.4 AU. Planetary and Space Science, 53, 3–17.
Madey, T. E., Yakshinsky, B. V., Ageev, V. N., and Johnson, R. E. (1998). Desorption of alkali atoms and ions from oxide surfaces: relevance to origins of Na and K in atmosphere of Mercury and the moon. Journal of Geophysical Research, 103, 5873– 5887.
McClintock, W. E., Vervack, R. J., Bradley, E. T., Killen, R. M., Mouawad, N., Sprague, A. L., Burger, M. H., Solomon, S. C., and Izenberg, N. R. (2009). MESSENGER observations of Mercury’s exosphere: detection of magnesium and distribution of con- stituents. Science, 324, 610–613.
McGrath, M. A., Johnson, R. E., and Lanzerotti, L. J. (1986). Sputtering of sodium on the planet Mercury. Nature, 323, 694–696.
Milillo, A., Wurz, P., Orsini, S., Delcourt, D., Kallio, E., Killen, R. M., Lammer, H., Massetti, S., Mura, A., Barabash, S., Cremonese, G., Daglis, I. A., Angelis, E., Lellis, A. M., Livi, S., Mangano, V., and Torkar, K. (2005). Surface-exosphere- magnetosphere system of Mercury. Space Science Reviews, 117, 397–443.
Mouawad, N., Burger, M. H., Killen, R. M., Potter, A. E., McClintock, W. E., Vervack, R. J., Bradley, E. T., Benna, M., and Naidu, S. (2011). Constraints on mercury’s na exosphere: Combined messenger and ground-based data. Icarus, 211, 21–36.
Mu ̈ller, J., Simon, S., Motschmann, U., Schu ̈le, J., Glassmeier, K.-H., and Pringle, G. J. (2011). A.I.K.E.F.: adaptive hybrid model for space plasma simulations. Computer Physics Communications, 182, 946–966.
Mu ̈ller, J., Simon, S., Wang, Y.-C., Motschmann, U., Heyner, D., Schu ̈le, J., Ip, W.-H., Kleindienst, G., and Pringle, G. J. (2012). Origin of Mercury’s double magnetopause: 3d hybrid simulation study with A.I.K.E.F. Icarus, 218, 666–687.
Mura, A., Milillo, A., Orsini, S., and Massetti, S. (2007). Numerical and analytical model of Mercury’s exosphere: dependence on surface and external conditions. Planetary and Space Science, 55, 1569–1583.
Mura, A., Orsini, S., Milillo, A., Delcourt, D., Lellis, A. M., Angelis, E., and Massetti, S. (2006). Neutral atoms emission from Mercury. In Advances in Geosciences (pp. 37–50). World Scientific Publishing Co. Pte. Ltd, Singapore, Hackensack and London volume 3.
Mura, A., Wurz, P., Lichtenegger, H. I. M., Schleicher, H., Helmut, L., Delcourt, D., Milillo, A., Orsini, S., Massetti, S., and Khodachenko, M. L. (2009). The sodium exosphere of Mercury: comparison between observations during Mercury’s transit and model results. Icarus, 200, 1–11.
Murray, C. D., and Dermott, S. F. (1999). Solar System Dynamics. Cambridge Univer- sity Press.
Nash, D. B., Matson, D. L., Johnson, T. V., and Fanale, F. P. (1975). Na-D line emission from rock specimens by proton bombardment - implications for emissions from Jupiter’s satellite Io. Journal of Geophysical Research, 80, 1875–1879.
Ness, N. F., Behannon, K. W., Lepping, R. P., Whang, Y. C., and Schatten, K. H. (1974). Magnetic field observations near Mercury: Preliminary results from Mariner 10. Science, 185, 151–160.
Omidi, N., Blanco-Cano, X., Russell, C. T., and Karimabadi, H. (2006). Global hybrid simulations of solar wind interactions with Mercury: Magnetospheric boundaries. Ad- vances in Space Research, 38, 632–638.
Orsini, S., Blomberg, L. G., Delcourt, D., Grard, R., Massetti, S., Seki, K., and Slavin, J. (2007). Magnetosphere-exosphere-surface coupling at Mercury. Space Science Re- views, 132, 551–573.
O ̈zisik,M.N.(1968).Boundaryvalueproblemsofheatconduction.chapterNumerical solution of heat-conduction problems. (pp. 389–454). General Publishing Company, Ltd., Constable and Company, Ltd., Ontario, Canada, London.
Potter, A. E. (1995). Chemical sputtering could produce sodium vapor and ice on Mercury. Geophysical Research Letters, 22, 3289–3292.
Potter, A. E., and Killen, R. M. (2008). Observations of the sodium tail of Mercury. Icarus, 194, 1–12.
Potter, A. E., Killen, R. M., and Morgan, T. H. (1999). Rapid changes in the sodium exosphere of Mercury. Planetary and Space Science, 47, 1141–1148.
Potter, A. E., Killen, R. M., and Morgan, T. H. (2002). The sodium tail of Mercury. Meteoritics and Planetary Science, 37, 1165–1172.
Potter, A. E., Killen, R. M., and Morgan, T. H. (2007). Solar radiaiton acceleration effects on Mercury sodium emission. Icarus, 186, 571–580.
Potter, A. E., Killen, R. M., and Sarantos, M. (2006). Spatial distribution of sodium on Mercury. Icarus, 181, 1–12.
Potter, A. E., and Morgan, T. H. (1985). Discovery of sodium in the atmosphere of Mercury. Science, 229, 651–653.
Potter, A. E., and Morgan, T. H. (1986). Potassium in the atmosphere of Mercury. Icarus, 67, 336–340.
Potter, A. E., and Morgan, T. H. (1987). Variation of sodium on Mercury with solar radiation pressure. Icarus, 71, 472–477.
Russell, C. T., Baker, D. N., and Slavin, J. A. (1988). Mercury. chapter The magneto- sphere of Mercury. (pp. 514–561). University of Arizona Press.
Sarantos, M., Reiff, P. H., Hill, T. W., Killen, R. M., and Urquhart, A. L. (2001). A Bx-interconnected magnetosphere model for Mercury. Planetary and Space Science, 49, 1629–1635.
Sarantos, M., and Slavin, J. A. (2009). On the possible formation of Alfv ́en wings at Mercury during encounters with coronal mass ejections. Geophysical Research Letters, 36, L04107.
Sarantos, M., Slavin, J. A., Benna, M., Boardsen, S. A., Killen, R. M., Schriver, D., and Tr ́avn ́ıˇcek, P. (2009). Sodium-ion pickup observed above the magnetopause during messenger’s first mercury flyby: Constraints on neutral exospheric models. Geophys- ical Research Letters, 36, L04106.
Schleicher, H., Wiedemann, G., W ̈ohl, H., Berkefeld, T., and Soltau, D. (2004). Detec- tion of neutral sodium above Mercury during the transit on 2003 may 7. Astronomy and Astrophysics, 425, 1119–1124.
Schmidt, C. A., Wilson, J. K., Baumgardner, J., and Mendillo, M. (2010). Orbital effects on Mercury’s escaping sodium exosphere. Icarus, 207, 9–16.
Shemansky, D. E., and Broadfoot, A. L. (1977). Interaction of the surfaces of the moon and Mercury with their exospheric atmospheres. Reviews of Geophysics and Space Physics, 15, 491–499.
Sieveka, E. M., and Johnson, R. E. (1984). Ejection of atoms and molecules from Io by plasma-ion impact. Astrophysical Journal, 287, 418–426.
Simon, S., Bagdonat, T., Motschmann, U., and Glassmeier, K.-H. (2006). Plasma envi- ronment of magnetized asteroids: a 3-d hybrid simulation study. Annales Geophysicae, 24, 407–414.
Siscoe, G., and Christopher, L. (1975). Variations in the solar wind stand-off distance at Mercury. Geophysical Research Letters, 2, 158–160.
Slavin, J. A., Acun ̃a, M. H., Anderson, B. J., Baker, D. N., Benna, M., Boardsen, S. A., Gloeckler, G., Gold, R. E., Ho, G. C., Korth, H., Krimigis, S. M., McNutt, R. L., Raines, J. M., Sarantos, M., Schriver, D., Solomon, S. C., Tr ́avn ́ıˇcek, P., and Zur- buchen, T. H. (2009). Messenger observations of magnetic reconnection in mercury’s magnetosphere. Science, 324, 606–610.
Slavin, J. A., Acun ̃a, M. H., Anderson, B. J., Baker, D. N., Benna, M., Gloeckler, G., Gold, R. E., Ho, G. C., Killen, R. M., Korth, H., Krimigis, S. M., McNutt, R. L., Nittler, L. R., Raines, J. M., Schriver, D., Solomon, S. C., Starr, R. D., Tr ́avn ́ıˇcek, P., and Zurbuchen, T. H. (2008). Mercury’s magnetosphere after MESSENGER’s first flyby. Science, 321, 85–89.
Smyth, W. H. (1979). Io’s sodium cloud - explanation of the east-west asymmetries. Astrophysical Journal, 234, 1148–1153.
Smyth, W. H. (1986). Nature and variability of Mercury’s sodium atmosphere. Nature, 323, 696–699.
Smyth, W. H., and Marconi, M. L. (1995). Theoretical overview and modeling of the sodium and potassium atmosphere of Mercury. Astrophysical Journal, 441, 839–864.
Sonett, C. P., and Colburn, D. S. (1968). The principle of solar wind induced planetary dynamos. Physics of the Earth and planetary interiors, 1, 326–346.
Sprague, A. L., Kozlowski, R. W. H., Hunten, D. M., Schneider, N. M., Domingue, D. L., Wells, W. K., Schmitt, W., and Fink, U. (1997). Distribution and abundance of sodium in Mercury’s atmosphere, 1985-1988. Icarus, 129, 506–527.
Tipler, P. A., and Llewellyn, R. A. (2002). Modern Physics. (4th ed.). 41 Madison Avenue, New York, NY 10010: W. H. Freeman and Company.
Tr ́avn ́ıˇcek, P., Hellinger, P., and Schriver, D. (2007). Structure of Mercury’s magneto- sphere for different pressure of the solar wind: three dimensional hybrid simulations. Geophysical Research Letters, 34, L05104.
Tr ́avn ́ıˇcek, P., Hellinger, P., Schriver, D., Herˇc ́ık, D., Slavin, J. A., and Anderson, B. J. (2009). Kinetic instabilities in Mercury’s magnetosphere: three-dimensional simulation results. Geophysical Research Letters, 36, L07104.
Vernazza, P., Brunetto, R., Strazzulla, G., Fulchignoni, M., Rochette, P., Meyer-Vernet, N., and Zouganelis, I. (2006). Asteroid colors: a novel tool for magnetic field detection? the case of Vesta. Astronomy and Astrophysics, 451, L43–L46.
Vervack, R. J., McClintock, W. E., Killen, R. M., Sprague, A. L., Anderson, B. J., Burger, M. H., Bradley, E. T., Mouawad, N., Solomon, S. C., and Izenberg, N. R. (2010). Mercury’s complex exosphere: results from MESSENGER’s third flyby. Sci- ence, 329, 672–675.
Wang, Y.-C., and Ip, W.-H. (2008). A surface thermal model and exospheric ballistic transport code of planet Mercury. Advances in Space Research, 42, 34–39.
Wang, Y.-C., and Ip, W.-H. (2011). Source dependency of exospheric sodium on Mer- cury. Icarus, 216, 387–402.
Wang, Y.-C., Mu ̈ller, J., Ip, W.-H., and Motschmann, U. (2011). A 3d hybrid simulation study of the electromagnetic field distributions in the lunar wake. Icarus, 216, 415– 425.
Wang, Y.-C., Mu ̈ller, J., Motschmann, U., and Ip, W.-H. (2010). A hybrid simulation of Mercury’s magnetosphere for the MESSENGER encounters in year 2008. Icarus, 209, 46–52.
Wiens, R. C., Burnett, D. S., Calaway, W. F., Hansen, C. S., Lykke, K. R., and Pellin, M. J. (1997). Sputtering products of sodium sulfate: implications for Io’s surface and for sodium-bearing molecules in the Io torus. Icarus, 128, 386–397.
Wieser, M., Barabash, S., Futaana, Y., Holmstr ̈om, M., Bhardwaj, A., Sridharan, R., Dhanya, M. B., Schaufelberger, A., Wurz, P., and Asamura, K. (2010). First observa- tion of a mini-magnetosphere above a lunar magnetic anomaly using energetic neutral atoms. Geophysical Research Letters, 37, L05103.
Wurz, P., and Lammer, H. (2003). Monte-Carlo simulation of Mercury’s exosphere. Icarus, 164, 1–13.
Yakshinskiy, B. V., and Madey, T. E. (1999). Photon-simulated desorption as a sub- stantial source of sodium in the lunar atmosphere. Nature, 400, 642–644.
Zurbuchen, T. H., Koehn, P., Fisk, L. A., Gombosi, T., Gloeckler, G., and Kabin, K. (2004). On the space environment of Mercury. Advances in Space Research, 33, 1884–1889.
|