Observational constraints on the process and products of Martian serpentinization

The alteration of olivine-rich rocks to serpentine minerals, (hydr)oxides, and aqueous hydrogen through serpentinization is long thought to have influenced the distribution of habitable environments on early Mars and the evolution of the early Martian hydrosphere and atmosphere. Nevertheless, the planetary importance of Martian serpentinization has remained a matter of debate. To constrain the process and products of Martian serpentinization, we studied serpentinized iron-rich olivines from the 1.1-billion-year Duluth Complex. These data indicate that serpentinized iron-rich olivine would have been accompanied by a fivefold increase in hydrogen production relative to serpentinized terrestrial mantle peridotites. In contrast to previous expectations, this style of serpentinization yields hisingerite as the dominant iron serpentine mineral at comparatively low temperature and pH, consistent with meteorite mineralogy and in situ rover data. The widespread occurrence of oxidized iron-bearing phyllosilicates in highly magnetized regions of the Martian crust supports the hypothesis that serpentinization was more pervasive on early Mars than currently estimated.

[1]  B. Tutolo,et al.  PyGeochemCalc: A Python package for geochemical thermodynamic calculations from ambient to deep Earth conditions , 2022, Chemical Geology.

[2]  L. Nittler,et al.  Organic synthesis associated with serpentinization and carbonation on early Mars , 2022, Science.

[3]  E. Shock,et al.  Decreasing extents of Archean serpentinization contributed to the rise of an oxidized atmosphere , 2021, Nature Communications.

[4]  T. McCollom,et al.  Hydrogen generation from serpentinization of iron-rich olivine on Mars, icy moons, and other planetary bodies , 2021, Icarus.

[5]  B. Tutolo,et al.  Geochemical evaluation of glauconite carbonation during sedimentary diagenesis , 2021 .

[6]  W. Banerdt,et al.  Thickness and structure of the martian crust from InSight seismic data , 2021, Science.

[7]  W. Banerdt,et al.  Upper mantle structure of Mars from InSight seismic data , 2021, Science.

[8]  D. Ming,et al.  Brine-driven destruction of clay minerals in Gale crater, Mars , 2021, Science.

[9]  B. Ehlmann,et al.  Long-term drying of Mars by sequestration of ocean-scale volumes of water in the crust , 2021, Science.

[10]  A. Knoll,et al.  A coupled model of episodic warming, oxidation and geochemical transitions on early Mars , 2021, Nature Geoscience.

[11]  E. Ellison,et al.  Quantitative microscale Fe redox imaging by multiple energy X-ray fluorescence mapping at the Fe K pre-edge peak , 2020, American Mineralogist.

[12]  W. Seyfried,et al.  A seawater throttle on H2 production in Precambrian serpentinizing systems , 2020, Proceedings of the National Academy of Sciences.

[13]  Jens Klump,et al.  pyrolite: Python for geochemistry , 2020, J. Open Source Softw..

[14]  Y. Podladchikov,et al.  Instantaneous rock transformations in the deep crust driven by reactive fluid flow , 2020, Nature Geoscience.

[15]  J. Grotzinger,et al.  The origin of life as a planetary phenomenon , 2020, Science Advances.

[16]  E. Ellison,et al.  A synthesis and meta-analysis of the Fe chemistry of serpentinites and serpentine minerals , 2020, Philosophical Transactions of the Royal Society A.

[17]  S. McLennan,et al.  The Sedimentary Cycle on Early Mars , 2019, Annual Review of Earth and Planetary Sciences.

[18]  B. Tutolo,et al.  Serpentine–Hisingerite Solid Solution in Altered Ferroan Peridotite and Olivine Gabbro , 2019, Minerals.

[19]  E. Cloutis,et al.  Raman and reflectance spectroscopy of serpentinites and related hydrated silicates: Effects of physical properties and observational parameters, and implications for detection and characterization on Mars , 2018, Planetary and Space Science.

[20]  J. Bandfield,et al.  A search for minerals associated with serpentinization across Mars using CRISM spectral data , 2018, Icarus.

[21]  J. Moore,et al.  The divergent fates of primitive hydrospheric water on Earth and Mars , 2017, Nature.

[22]  K. Michibayashi,et al.  Mantle hydration along outer-rise faults inferred from serpentinite permeability , 2017, Scientific Reports.

[23]  M. Russell,et al.  Methane: Fuel or Exhaust at the Emergence of Life? , 2017, Astrobiology.

[24]  B. W. Evans,et al.  Serpentine, Iron-rich Phyllosilicates and Fayalite Produced by Hydration and Mg Depletion of Peridotite, Duluth Complex, Minnesota, USA , 2017 .

[25]  J. Head,et al.  Transient reducing greenhouse warming on early Mars , 2016, 1610.09697.

[26]  A. Templeton,et al.  Temperature trends for reaction rates, hydrogen generation, and partitioning of iron during experimental serpentinization of olivine , 2016 .

[27]  W. Seyfried,et al.  Nanoscale constraints on porosity generation and fluid flow during serpentinization , 2016 .

[28]  W. Seyfried,et al.  The Lost City hydrothermal system: Constraints imposed by vent fluid chemistry and reaction path models on subseafloor heat and mass transfer processes , 2015 .

[29]  J. Bishop,et al.  Constraints on the crystal-chemistry of Fe/Mg-rich smectitic clays on Mars and links to global alteration trends , 2014 .

[30]  Scott M. McLennan,et al.  Constraints on abundance, composition, and nature of X‐ray amorphous components of soils and rocks at Gale crater, Mars , 2014 .

[31]  J. Bridges,et al.  Ferric saponite and serpentine in the nakhlite martian meteorites , 2014 .

[32]  J. Kasting,et al.  Warming early Mars with CO 2 and H 2 , 2014, 1405.6701.

[33]  S. Humphris,et al.  Magnetite in seafloor serpentinite—Some like it hot , 2014 .

[34]  R. V. Morris,et al.  X-ray Diffraction Results from Mars Science Laboratory: Mineralogy of Rocknest at Gale Crater , 2013, Science.

[35]  T. McCollom,et al.  Compositional controls on hydrogen generation during serpentinization of ultramafic rocks , 2013 .

[36]  F. Leblanc,et al.  The fate of early Mars' lost water: The role of serpentinization , 2013 .

[37]  Jean-Pierre Bibring,et al.  Hydrous minerals on Mars as seen by the CRISM and OMEGA imaging spectrometers: Updated global view , 2013 .

[38]  W. Seyfried,et al.  Vent fluid chemistry of the Rainbow hydrothermal system (36°N, MAR): Phase equilibria and in situ pH controls on subseafloor alteration processes , 2011 .

[39]  S. Murchie,et al.  Geologic setting of serpentine deposits on Mars , 2010 .

[40]  Harry Y. McSween,et al.  Elemental Composition of the Martian Crust , 2009, Science.

[41]  B. W. Evans Control of the Products of Serpentinization by the Fe2+Mg –1 Exchange Potential of Olivine and Orthopyroxene , 2008 .

[42]  Victoria E. Hamilton,et al.  Global distribution, composition, and abundance of olivine on the surface of Mars from thermal infrared data , 2008 .

[43]  M. D. Dyar,et al.  Reflectance and emission spectroscopy study of four groups of phyllosilicates: smectites, kaolinite-serpentines, chlorites and micas , 2008, Clay Minerals.

[44]  C. Oze,et al.  Serpentinization and the inorganic synthesis of H2 in planetary surfaces , 2007 .

[45]  D. Blake,et al.  Serpentinization and its implications for life on the early Earth and Mars. , 2006, Astrobiology.

[46]  W. McDonough,et al.  The composition of the Earth , 1995 .

[47]  J. Pasteris,et al.  Interactions of mixed volatile-brine fluids in rocks of the southwestern footwall of the Duluth Complex, Minnesota; evidence from aqueous fluid inclusions , 1995 .

[48]  N. I. Taib,et al.  Hydrothermal alteration in the Babbitt Cu-Ni deposit, Duluth Complex; mineralogy and hydrogen isotope systematics , 1993 .

[49]  P. Hudleston,et al.  “Fracture cleavage” in the Duluth Complex, northeastern Minnesota , 1986 .

[50]  Don L. Anderson,et al.  Mineralogy and composition of the upper mantle , 1984 .

[51]  P. Sims Geologic map of Minnesota : bedrock geology , 1970 .