Hydrothermal systems associated with martian impact craters

被引:120
|
作者
Rathbun, JA
Squyres, SW
机构
[1] Lowell Observ, Flagstaff, AZ 86001 USA
[2] Cornell Univ, Ctr Radiophys & Space Res, Ithaca, NY 14853 USA
来源
ICARUS | 2002年 / 157卷 / 02期
基金
美国国家航空航天局;
关键词
Mars; Mars surface; exobiology; impact processes;
D O I
10.1006/icar.2002.6838
中图分类号
P1 [天文学];
学科分类号
0704 ;
摘要
With widespread evidence of both heat sources and water (either liquid or solid), hydrothermal systems are likely to have existed on Mars. We model hydrothermal systems in two sizes of fresh impact craters, one simple and one complex, and find that a hydrothermal system forms on the crater floor. In the larger complex craters with a substantial melt sheet, a lake can form, even under current martian atmospheric conditions. By comparing these hydrothermal systems to those that exist and have been studied extensively on the Earth, we make predictions as to the types of minerals that could be precipitated and the potential habitability of such systems by primitive organisms. (C) 2002 Elsevier Science (USA).
引用
收藏
页码:362 / 372
页数:11
相关论文
共 50 条
  • [21] UTILIZING SMALL IMPACT CRATERS TO CLARIFY THE HISTORY OF MARTIAN SURFACES
    Hartmann, W. K.
    Daubar, I.
    METEORITICS & PLANETARY SCIENCE, 2016, 51 : A315 - A315
  • [22] HYDROTHERMAL ALTERATION OF MELT ROCKS IN IMPACT CRATERS
    ALLEN, CC
    KEIL, K
    METEORITICS, 1981, 16 (04): : 288 - 289
  • [23] Outline model of hydrothermal circulation in impact craters
    Transaction (Doklady) of the Russian Academy of Sciences: Earth Science Sections, 1996, 337A (06):
  • [24] Fluidized Ejecta Morphologies and Degradation Processes of Martian Impact Craters
    Suzuki, Ayako I.
    Kurita, Kei
    JOURNAL OF GEOGRAPHY-CHIGAKU ZASSHI, 2016, 125 (01) : 13 - 33
  • [25] Puncturing Mars: How impact craters interact with the Martian cryosphere
    Schwenzer, S. P.
    Abramov, O.
    Allen, C. C.
    Clifford, S. M.
    Cockell, C. S.
    Filiberto, J.
    Kring, D. A.
    Lasue, J.
    McGovern, P. J.
    Newsom, H. E.
    Treiman, A. H.
    Vaniman, D. T.
    Wiens, R. C.
    EARTH AND PLANETARY SCIENCE LETTERS, 2012, 335 : 9 - 17
  • [26] Detection and Boundary Extraction of Martian Impact Craters by a Pyramidal Approach
    Christoff, Nicole
    Manolova, Agata
    2019 14TH INTERNATIONAL CONFERENCE ON ADVANCED TECHNOLOGIES, SYSTEMS AND SERVICES IN TELECOMMUNICATIONS (TELSIKS 2019), 2019, : 384 - 387
  • [27] LOCALIZATION OF MARTIAN RIDGES BY IMPACT CRATERS - MECHANICAL AND CHRONOLOGICAL IMPLICATIONS
    ALLEMAND, P
    THOMAS, PG
    JOURNAL OF GEOPHYSICAL RESEARCH-PLANETS, 1995, 100 (E2) : 3251 - 3262
  • [28] LABORATORY SIMULATIONS OF WIND EROSION AND DEPOSITION ASSOCIATED WITH MARTIAN CRATERS
    GREELEY, R
    POLLACK, JB
    IVERSEN, JD
    TRANSACTIONS-AMERICAN GEOPHYSICAL UNION, 1973, 54 (11): : 1127 - 1127
  • [29] Biological potential of martian hydrothermal systems
    Varnes, ES
    Jakosky, BM
    McCollom, TM
    ASTROBIOLOGY, 2003, 3 (02) : 407 - 414
  • [30] Ejecta thickness and structural rim uplift measurements of Martian impact craters: Implications for the rim formation of complex impact craters
    Sturm, Sebastian
    Kenkmann, Thomas
    Hergarten, Stefan
    JOURNAL OF GEOPHYSICAL RESEARCH-PLANETS, 2016, 121 (06) : 1026 - 1053
12345