Impact-generated hydrothermal systems on Earth and Mars

It has long been suggested that hydrothermal systems might have provided habitats for the origin and evolution of early life on Earth, and possibly other planets such as Mars. In this contribution we show that most impact events that result in the formation of complex impact craters (i.e., >2–4 and >5–10 km diameter on Earth and Mars, respectively) are potentially capable of generating a hydrothermal system. Consideration of the impact cratering record on Earth suggests that the presence of an impact crater lake is critical for determining the longevity and size of the hydrothermal system. We show that there are six main locations within and around impact craters on Earth where impact-generated hydrothermal deposits can form: (1) crater-fill impact melt rocks and melt-bearing breccias; (2) interior of central uplifts; (3) outer margin of central uplifts; (4) impact ejecta deposits; (5) crater rim region; and (6) post-impact crater lake sediments. We suggest that these six locations are applicable to Mars as well. Evidence for impact-generated hydrothermal alteration ranges from discrete vugs and veins to pervasive alteration depending on the setting and nature of the system. A variety of hydrothermal minerals have been documented in terrestrial impact structures and these can be grouped into three broad categories: (1) hydrothermally-altered target-rock assemblages; (2) primary hydrothermal minerals precipitated from solutions; and (3) secondary assemblages formed by the alteration of primary hydrothermal minerals. Target lithology and the origin of the hydrothermal fluids strongly influences the hydrothermal mineral assemblages formed in these post-impact hydrothermal systems. There is a growing body of evidence for impact-generated hydrothermal activity on Mars; although further detailed studies using high-resolution imagery and multispectral information are required. Such studies have only been done in detail for a handful of martian craters. The best example so far is from Toro Crater (Marzo, G.A., Davila, A.F., Tornabene, L.L., Dohm, J.M., Fairen, A.G., Gross, C., Kneissl, T., Bishop, J.L., Roush, T.L., Mckay, C.P. [2010]. Icarus 208, 667–683). We also present new evidence for impact-generated hydrothermal deposits within an unnamed ∼32-km diameter crater ∼350 km away from Toro and within the larger Holden Crater. Synthesizing observations of impact craters on Earth and Mars, we suggest that if there was life on Mars early in its history, then hydrothermal deposits associated with impact craters may provide the best, and most numerous, opportunities for finding preserved evidence for life on Mars. Moreover, hydrothermally altered and precipitated rocks can provide nutrients and habitats for life long after hydrothermal activity has ceased.

[1]  D. Kring,et al.  Numerical modeling of an impact‐induced hydrothermal system at the Sudbury crater , 2003 .

[2]  F. Hörz Ejecta of the Ries Crater, Germany , 1982 .

[3]  H. Newsom,et al.  Hydrothermal alteration at the Lonar Lake impact structure, India: Implications for impact cratering on Mars , 2003 .

[4]  D. Brownlee,et al.  METEORITICS & PLANETARY SCIENCE , 2014 .

[5]  T. Kenkmann,et al.  Radial transpression ridges: A new structural feature of complex impact craters , 2000 .

[6]  Pascal Lee,et al.  Impact‐induced hydrothermal activity within the Haughton impact structure, arctic Canada: Generation of a transient, warm, wet oasis , 2001 .

[7]  Raymond E. Arvidson,et al.  A synthesis of Martian aqueous mineralogy after 1 Mars year of observations from the Mars Reconnaissance Orbiter , 2009 .

[8]  The Origin of Planetary Impactors in the Inner Solar System , 2005, Science.

[9]  D. Kring,et al.  Numerical modeling of impact‐induced hydrothermal activity at the Chicxulub crater , 2006 .

[10]  A. McEwen,et al.  HiRISE imaging of impact megabreccia and sub-meter aqueous strata in Holden Crater, Mars , 2008 .

[11]  R. Wiens,et al.  Puncturing Mars: How impact craters interact with the Martian cryosphere , 2012 .

[12]  D. Kring,et al.  Impact-generated hydrothermal systems capable of forming phyllosilicates on Noachian Mars , 2009 .

[13]  T. Encrenaz,et al.  Global Mineralogical and Aqueous Mars History Derived from OMEGA/Mars Express Data , 2006, Science.

[14]  S. Murchie,et al.  Composition, Morphology, and Stratigraphy of Noachian Crust around the Isidis basin , 2009 .

[15]  A. Boyce,et al.  Sulfur isotope signatures for rapid colonization of an impact crater by thermophilic microbes , 2010 .

[16]  Raymond E. Arvidson,et al.  Compact Reconnaissance Imaging Spectrometer for Mars investigation and data set from the Mars Reconnaissance Orbiter's primary science phase , 2009 .

[17]  M. Malin,et al.  Impact‐induced overland fluid flow and channelized erosion at Lyot Crater, Mars , 2010 .

[18]  Jean-Pierre Bibring,et al.  Subsurface water and clay mineral formation during the early history of Mars , 2011, Nature.

[19]  B. Ivanov,et al.  Cooling of the Kärdla impact crater: II. Impact and geothermal modeling , 2005 .

[20]  H. Melosh,et al.  A geomorphic analysis of Hale crater, Mars: The effects of impact into ice-rich crust , 2011 .

[21]  C. Cockell,et al.  The microbe–mineral environment and gypsum neogenesis in a weathered polar evaporite , 2010, Geobiology.

[22]  J. Grotzinger,et al.  Paleoclimate of Mars as captured by the stratigraphic record in Gale Crater , 2010 .

[23]  Nathalie A. Cabrol,et al.  Hydrogeologic Evolution of Gale Crater and Its Relevance to the Exobiological Exploration of Mars , 1999 .

[24]  J. Parnell,et al.  Microbial colonization in impact-generated hydrothermal sulphate deposits, Haughton impact structure, and implications for sulphates on Mars , 2004, International Journal of Astrobiology.

[25]  Gordon R. Osinski,et al.  Tectonics of complex crater formation as revealed by the Haughton impact structure, Devon Island, Canadian High Arctic , 2005 .

[26]  D. Ames,et al.  Dating of a regional hydrothermal system induced by the 1850 Ma Sudbury impact event , 1998 .

[27]  G. Benedix,et al.  A multidisciplinary study of silica sinter deposits with applications to silica identification and detection of fossil life on Mars , 2008 .

[28]  J. Dohm,et al.  Evidence for Hesperian impact-induced hydrothermalism on Mars , 2010 .

[29]  J. Spray,et al.  The nature of the groundmass of surficial suevite from the Ries impact structure, Germany, and constraints on its origin , 2004 .

[30]  R. L. Penn,et al.  Two-step growth of goethite from ferrihydrite. , 2006, Langmuir : the ACS journal of surfaces and colloids.

[31]  G. Osinski,et al.  Intra‐crater sedimentary deposits at the Haughton impact structure, Devon Island, Canadian High Arctic , 2005 .

[32]  M. D. Stokes,et al.  Microbiology and Vegetation of Micro-oases and Polar Desert, Haughton Impact Crater, Devon Island, Nunavut, Canada , 2001 .

[33]  H. Newsom,et al.  Location and sampling of aqueous and hydrothermal deposits in martian impact craters. , 2001, Astrobiology.

[34]  J. Farmer Hydrothermal systems: Doorways to early biosphere evolution , 2000 .

[35]  D. Kring,et al.  Hydrothermal alteration in the core of the Yaxcopoil‐1 borehole, Chicxulub impact structure, Mexico , 2004 .

[36]  T. Hode,et al.  Evidence of Ancient Microbial Life in an Impact Structure and Its Implications for Astrobiology , 2009 .

[37]  浦辺 徹郎 "Hydrothermal Mineral Deposits":Principles and Fundamental Concepts for the Exploration Geologists Franco Pirajno 著 , 1996 .

[38]  J. Schopf,et al.  Evidence of Archean life: Stromatolites and microfossils , 2007 .

[39]  K. Pope,et al.  Impact-Generated Hydrothermal System — Constraints from the Large Paleoproterozoic Sudbury Crater, Canada , 2006 .

[40]  J. Seckbach,et al.  From Fossils to Astrobiology , 2008 .

[41]  K. Kirsimäe,et al.  Impact‐Induced Hydrothermal Activity , 2012 .

[42]  M. Naumov Impact-Generated Hydrothermal Systems: Data from Popigai, Kara, and Puchezh-Katunki Impact Structures , 2002 .

[43]  G. Arp Lacustrine bioherms, spring mounds, and marginal carbonates of the Ries-impact-crater (Miocene, Southern Germany) , 1995 .

[44]  S. Murchie,et al.  Detection of Hydrated Silicates in Crustal Outcrops in the Northern Plains of Mars , 2010, Science.

[45]  R. Grieve,et al.  Observations at terrestrial impact structures: Their utility in constraining crater formation , 2004 .

[46]  R. Grieve Economic natural resource deposits at terrestrial impact structures , 2005, Geological Society, London, Special Publications.

[47]  M. Cintala,et al.  An analysis of differential impact melt‐crater scaling and implications for the terrestrial impact record , 1992 .

[48]  B. Ivanov,et al.  Impact cratering in H2O‐bearing targets on Mars: Thermal field under craters as starting conditions for hydrothermal activity , 2011 .

[49]  Yatsuka Nakamura,et al.  Hf, Zr, and REE partition coefficients between ilmenite and liquid: Implications for lunar petrogenesis , 1986 .

[50]  K. Kirsimäe,et al.  Post‐impact alteration of surficial suevites in Ries crater, Germany: Hydrothermal modification or weathering processes? , 2008 .

[51]  D. Ames,et al.  Geology of the Giant Sudbury Polymetallic Mining Camp, Ontario, Canada , 2008 .

[52]  Robert B. Leighton,et al.  The Surface of Mars , 2007 .

[53]  N. Izenberg,et al.  Hydrated silicate minerals on Mars observed by the Mars Reconnaissance Orbiter CRISM instrument , 2008, Nature.

[54]  Raymond R. Anderson,et al.  The Manson impact structure, Iowa : anatomy of an impact crater , 1996 .

[55]  G. Southam,et al.  The preservation and degradation of filamentous bacteria and biomolecules within iron oxide deposits at Rio Tinto, Spain , 2011, Geobiology.

[56]  Kevin R. Housen,et al.  Impact Cratering: A Geologic Process , 1987 .

[57]  G. Brakenridge,et al.  Ancient hot springs on Mars: Origins and paleoenvironmental significance of small Martian valleys , 1985 .

[58]  K. Keil,et al.  Fluidization and hydrothermal alteration of the suevite deposit at the Ries Crater, West Germany, and implications for Mars , 1986 .

[59]  J. Parnell,et al.  The transfer of organic signatures from bedrock to sediment , 2008 .

[60]  John Parnell,et al.  A case study of impact‐induced hydrothermal activity: The Haughton impact structure, Devon Island, Canadian High Arctic , 2005 .

[61]  F. Nimmo,et al.  Martian post-impact hydrothermal systems incorporating freezing , 2010 .

[62]  M. Naumov Principal features of impact‐generated hydrothermal circulation systems: mineralogical and geochemical evidence , 2005 .

[63]  L. Crossey,et al.  Post-impact hydrothermal alteration of the Manson impact structure , 1996 .

[64]  Wolfgang Fink,et al.  Exploration of hydrothermal targets on Mars , 2007 .

[65]  Gordon R. Osinski,et al.  Impact ejecta emplacement on terrestrial planets , 2011 .

[66]  H. Newsom Hydrothermal alteration of impact melt sheets with implications for Mars , 1980 .

[67]  C. Allen,et al.  ∼1.8 Ga iron-mineralized microbiota from the Gunflint Iron Formation, Ontario, Canada: implications for Mars , 2004 .

[68]  S. Squyres,et al.  Hydrothermal systems associated with martian impact craters , 2002 .

[69]  A. Neubeck,et al.  Putative fossil life in a hydrothermal system of the Dellen impact structure, Sweden , 2010, International Journal of Astrobiology.

[70]  K. Kirsimäe,et al.  Stable isotope composition of smectite in suevites at the Ries crater, Germany: Implications for hydrous alteration of impactites , 2010 .

[71]  S. Kelley,et al.  Two large meteorite impacts at the Cretaceous-Paleogene boundary , 2010 .

[72]  P. Schultz,et al.  Geological implications of impacts of large asteroids and comets on the earth , 1982 .

[73]  N. Cabrol,et al.  Distribution, Classification, and Ages of Martian Impact Crater Lakes , 1999 .

[74]  T. Hode,et al.  A hydrothermal system associated with the Siljan impact structure, Sweden--implications for the search for fossil life on Mars. , 2003, Astrobiology.

[75]  C. Hibbitts,et al.  Impact crater lakes on Mars , 1996 .

[76]  John F. Mustard,et al.  Identification of hydrated silicate minerals on Mars using MRO‐CRISM: Geologic context near Nili Fossae and implications for aqueous alteration , 2009 .

[77]  J. Gerring A case study , 2011, Technology and Society.

[78]  U. Schwertmann,et al.  Effect of pH on the Formation of Goethite and Hematite from Ferrihydrite , 1983 .

[79]  Pascal Lee,et al.  The biology of impact craters — a review , 2002, Biological reviews of the Cambridge Philosophical Society.

[80]  M. Glamoclija,et al.  Microbial Signatures from Impact-induced Hydrothermal Settings of the Ries Crater, Germany; A Preliminary SEM Study , 2007 .

[81]  G. Osinski Hydrothermal activity associated with the Ries impact event, Germany , 2005 .

[82]  T. Onstott,et al.  Stars of the terrestrial deep subsurface: A novel ‘star‐shaped’ bacterial morphotype from a South African platinum mine , 2008, Geobiology.

[83]  Michael H. Carr,et al.  Water on Mars , 1987, Nature.

[84]  David A. Kring,et al.  Impact‐induced hydrothermal activity on early Mars , 2005 .

[85]  J. Parnell,et al.  Weathering of post-impact hydrothermal deposits from the Haughton impact structure: implications for microbial colonization and biosignature preservation. , 2011, Astrobiology.