Evidence of Sulfate-Rich Fluid Alteration in Jezero Crater Floor, Mars

Sandra Siljeström; Andrew D. Czaja; Andrea Corpolongo; Eve L. Berger; An Y. Li; Emily Cardarelli; William Abbey; Sanford A. Asher; Luther W. Beegle; Kathleen C. Benison; Rohit Bhartia; Benjamin L. Bleefeld; Aaron S. Burton; Sergei V. Bykov; Benton Clark; Lauren DeFlores; Bethany L. Ehlmann; Teresa Fornaro; Allie Fox; Felipe Gómez; Kevin Hand; Nikole C. Haney; Keyron Hickman-Lewis; William F. Hug; Samara Imbeah; Ryan S. Jakubek; Linda C. Kah; Lydia Kivrak; Carina Lee; Yang Liu; Jesús Martínez-Frías; Francis M. McCubbin; Michelle Minitti; Kelsey Moore; Richard V. Morris; Jorge I. Núñez; Jeffrey T. Osterhout; Yu Yu Phua; Nicolas Randazzo; Joseph Razzell Hollis; Carolina Rodriguez; Ryan Roppel; Eva L. Scheller; Mark Sephton; Shiv K. Sharma; Sunanda Sharma; Kim Steadman; Andrew Steele; Michael Tice; Kyle Uckert; Scott VanBommel; Amy J. Williams; Kenneth H. Williford; Katherine Winchell; Megan Kennedy Wu; Anastasia Yanchilina; Maria Paz Zorzano

doi:10.1029/2023JE007989

Evidence of Sulfate-Rich Fluid Alteration in Jezero Crater Floor, Mars

Sandra Siljeström
, Andrew D. Czaja
, Andrea Corpolongo
, Eve L. Berger
, An Y. Li
, Emily Cardarelli
, William Abbey
, Sanford A. Asher
, Luther W. Beegle
, Kathleen C. Benison
, Rohit Bhartia
, Benjamin L. Bleefeld
, Aaron S. Burton
, Sergei V. Bykov
, Benton Clark
, Lauren DeFlores
, Bethany L. Ehlmann
, Teresa Fornaro
, Allie Fox
, Felipe Gómez

Kevin Hand, Nikole C. Haney, Keyron Hickman-Lewis, William F. Hug, Samara Imbeah, Ryan S. Jakubek, Linda C. Kah, Lydia Kivrak, Carina Lee, Yang Liu, Jesús Martínez-Frías, Francis M. McCubbin, Michelle Minitti, Kelsey Moore, Richard V. Morris, Jorge I. Núñez, Jeffrey T. Osterhout, Yu Yu Phua, Nicolas Randazzo, Joseph Razzell Hollis, Carolina Rodriguez, Ryan Roppel, Eva L. Scheller, Mark Sephton, Shiv K. Sharma, Sunanda Sharma, Kim Steadman, Andrew Steele, Michael Tice, Kyle Uckert, Scott VanBommel, Amy J. Williams, Kenneth H. Williford, Katherine Winchell, Megan Kennedy Wu, Anastasia Yanchilina, Maria Paz Zorzano

Department of Earth & Planetary Sciences

Research output: Contribution to journal › Article › peer-review

49 Scopus citations

Abstract

Sulfur plays a major role in martian geochemistry and sulfate minerals are important repositories of water. However, their hydration states on Mars are poorly constrained. Therefore, understanding the hydration and distribution of sulfate minerals on Mars is important for understanding its geologic, hydrologic, and atmospheric evolution as well as its habitability potential. NASA's Perseverance rover is currently exploring the Noachian-age Jezero crater, which hosts a fan-delta system associated with a paleolake. The crater floor includes two igneous units (the Séítah and Máaz formations), both of which contain evidence of later alteration by fluids including sulfate minerals. Results from the rover instruments Scanning Habitable Environments with Raman and Luminescence for Organics and Chemistry and Planetary Instrument for X-ray Lithochemistry reveal the presence of a mix of crystalline and amorphous hydrated Mg-sulfate minerals (both MgSO₄·[3–5]H₂O and possible MgSO₄·H₂O), and anhydrous Ca-sulfate minerals. The sulfate phases within each outcrop may have formed from single or multiple episodes of water activity, although several depositional events seem likely for the different units in the crater floor. Textural and chemical evidence suggest that the sulfate minerals most likely precipitated from a low temperature sulfate-rich fluid of moderate pH. The identification of approximately four waters puts a lower constraint on the hydration state of sulfate minerals in the shallow subsurface, which has implications for the martian hydrological budget. These sulfate minerals are key samples for future Mars sample return.

Original language	English
Article number	e2023JE007989
Journal	Journal of Geophysical Research: Planets
Volume	129
Issue number	1
DOIs	https://doi.org/10.1029/2023JE007989
State	Published - Jan 2024

Keywords

Mars
PIXL
Perseverance
SHERLOC
hydration
sulfate

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10.1029/2023JE007989

Cite this

Siljeström, S., Czaja, A. D., Corpolongo, A., Berger, E. L., Li, A. Y., Cardarelli, E., Abbey, W., Asher, S. A., Beegle, L. W., Benison, K. C., Bhartia, R., Bleefeld, B. L., Burton, A. S., Bykov, S. V., Clark, B., DeFlores, L., Ehlmann, B. L., Fornaro, T., Fox, A., ... Zorzano, M. P. (2024). Evidence of Sulfate-Rich Fluid Alteration in Jezero Crater Floor, Mars. Journal of Geophysical Research: Planets, 129(1), Article e2023JE007989. https://doi.org/10.1029/2023JE007989

@article{7e6a7f877d2049d4a3a99612cb797c38,

title = "Evidence of Sulfate-Rich Fluid Alteration in Jezero Crater Floor, Mars",

abstract = "Sulfur plays a major role in martian geochemistry and sulfate minerals are important repositories of water. However, their hydration states on Mars are poorly constrained. Therefore, understanding the hydration and distribution of sulfate minerals on Mars is important for understanding its geologic, hydrologic, and atmospheric evolution as well as its habitability potential. NASA's Perseverance rover is currently exploring the Noachian-age Jezero crater, which hosts a fan-delta system associated with a paleolake. The crater floor includes two igneous units (the S{\'e}{\'i}tah and M{\'a}az formations), both of which contain evidence of later alteration by fluids including sulfate minerals. Results from the rover instruments Scanning Habitable Environments with Raman and Luminescence for Organics and Chemistry and Planetary Instrument for X-ray Lithochemistry reveal the presence of a mix of crystalline and amorphous hydrated Mg-sulfate minerals (both MgSO4·[3–5]H2O and possible MgSO4·H2O), and anhydrous Ca-sulfate minerals. The sulfate phases within each outcrop may have formed from single or multiple episodes of water activity, although several depositional events seem likely for the different units in the crater floor. Textural and chemical evidence suggest that the sulfate minerals most likely precipitated from a low temperature sulfate-rich fluid of moderate pH. The identification of approximately four waters puts a lower constraint on the hydration state of sulfate minerals in the shallow subsurface, which has implications for the martian hydrological budget. These sulfate minerals are key samples for future Mars sample return.",

keywords = "Mars, PIXL, Perseverance, SHERLOC, hydration, sulfate",

author = "Sandra Siljestr{\"o}m and Czaja, \{Andrew D.\} and Andrea Corpolongo and Berger, \{Eve L.\} and Li, \{An Y.\} and Emily Cardarelli and William Abbey and Asher, \{Sanford A.\} and Beegle, \{Luther W.\} and Benison, \{Kathleen C.\} and Rohit Bhartia and Bleefeld, \{Benjamin L.\} and Burton, \{Aaron S.\} and Bykov, \{Sergei V.\} and Benton Clark and Lauren DeFlores and Ehlmann, \{Bethany L.\} and Teresa Fornaro and Allie Fox and Felipe G{\'o}mez and Kevin Hand and Haney, \{Nikole C.\} and Keyron Hickman-Lewis and Hug, \{William F.\} and Samara Imbeah and Jakubek, \{Ryan S.\} and Kah, \{Linda C.\} and Lydia Kivrak and Carina Lee and Yang Liu and Jes{\'u}s Mart{\'i}nez-Fr{\'i}as and McCubbin, \{Francis M.\} and Michelle Minitti and Kelsey Moore and Morris, \{Richard V.\} and N{\'u}{\~n}ez, \{Jorge I.\} and Osterhout, \{Jeffrey T.\} and Phua, \{Yu Yu\} and Nicolas Randazzo and Hollis, \{Joseph Razzell\} and Carolina Rodriguez and Ryan Roppel and Scheller, \{Eva L.\} and Mark Sephton and Sharma, \{Shiv K.\} and Sunanda Sharma and Kim Steadman and Andrew Steele and Michael Tice and Kyle Uckert and Scott VanBommel and Williams, \{Amy J.\} and Williford, \{Kenneth H.\} and Katherine Winchell and Wu, \{Megan Kennedy\} and Anastasia Yanchilina and Zorzano, \{Maria Paz\}",

note = "Publisher Copyright: {\textcopyright} 2024 Jet Propulsion Laboratory, California Institute of Technology. Journal of Geophysical Research: Planets published by Wiley Periodicals LLC on behalf of American Geophysical Union.",

year = "2024",

month = jan,

doi = "10.1029/2023JE007989",

language = "English",

volume = "129",

journal = "Journal of Geophysical Research: Planets",

issn = "2169-9097",

number = "1",

}

Siljeström, S, Czaja, AD, Corpolongo, A, Berger, EL, Li, AY, Cardarelli, E, Abbey, W, Asher, SA, Beegle, LW, Benison, KC, Bhartia, R, Bleefeld, BL, Burton, AS, Bykov, SV, Clark, B, DeFlores, L, Ehlmann, BL, Fornaro, T, Fox, A, Gómez, F, Hand, K, Haney, NC, Hickman-Lewis, K, Hug, WF, Imbeah, S, Jakubek, RS, Kah, LC, Kivrak, L, Lee, C, Liu, Y, Martínez-Frías, J, McCubbin, FM, Minitti, M, Moore, K, Morris, RV, Núñez, JI, Osterhout, JT, Phua, YY, Randazzo, N, Hollis, JR, Rodriguez, C, Roppel, R, Scheller, EL, Sephton, M, Sharma, SK, Sharma, S, Steadman, K, Steele, A, Tice, M, Uckert, K, VanBommel, S, Williams, AJ, Williford, KH, Winchell, K, Wu, MK, Yanchilina, A & Zorzano, MP 2024, 'Evidence of Sulfate-Rich Fluid Alteration in Jezero Crater Floor, Mars', Journal of Geophysical Research: Planets, vol. 129, no. 1, e2023JE007989. https://doi.org/10.1029/2023JE007989

TY - JOUR

T1 - Evidence of Sulfate-Rich Fluid Alteration in Jezero Crater Floor, Mars

AU - Siljeström, Sandra

AU - Czaja, Andrew D.

AU - Corpolongo, Andrea

AU - Berger, Eve L.

AU - Li, An Y.

AU - Cardarelli, Emily

AU - Abbey, William

AU - Asher, Sanford A.

AU - Beegle, Luther W.

AU - Benison, Kathleen C.

AU - Bhartia, Rohit

AU - Bleefeld, Benjamin L.

AU - Burton, Aaron S.

AU - Bykov, Sergei V.

AU - Clark, Benton

AU - DeFlores, Lauren

AU - Ehlmann, Bethany L.

AU - Fornaro, Teresa

AU - Fox, Allie

AU - Gómez, Felipe

AU - Hand, Kevin

AU - Haney, Nikole C.

AU - Hickman-Lewis, Keyron

AU - Hug, William F.

AU - Imbeah, Samara

AU - Jakubek, Ryan S.

AU - Kah, Linda C.

AU - Kivrak, Lydia

AU - Lee, Carina

AU - Liu, Yang

AU - Martínez-Frías, Jesús

AU - McCubbin, Francis M.

AU - Minitti, Michelle

AU - Moore, Kelsey

AU - Morris, Richard V.

AU - Núñez, Jorge I.

AU - Osterhout, Jeffrey T.

AU - Phua, Yu Yu

AU - Randazzo, Nicolas

AU - Hollis, Joseph Razzell

AU - Rodriguez, Carolina

AU - Roppel, Ryan

AU - Scheller, Eva L.

AU - Sephton, Mark

AU - Sharma, Shiv K.

AU - Sharma, Sunanda

AU - Steadman, Kim

AU - Steele, Andrew

AU - Tice, Michael

AU - Uckert, Kyle

AU - VanBommel, Scott

AU - Williams, Amy J.

AU - Williford, Kenneth H.

AU - Winchell, Katherine

AU - Wu, Megan Kennedy

AU - Yanchilina, Anastasia

AU - Zorzano, Maria Paz

N1 - Publisher Copyright: © 2024 Jet Propulsion Laboratory, California Institute of Technology. Journal of Geophysical Research: Planets published by Wiley Periodicals LLC on behalf of American Geophysical Union.

PY - 2024/1

Y1 - 2024/1

N2 - Sulfur plays a major role in martian geochemistry and sulfate minerals are important repositories of water. However, their hydration states on Mars are poorly constrained. Therefore, understanding the hydration and distribution of sulfate minerals on Mars is important for understanding its geologic, hydrologic, and atmospheric evolution as well as its habitability potential. NASA's Perseverance rover is currently exploring the Noachian-age Jezero crater, which hosts a fan-delta system associated with a paleolake. The crater floor includes two igneous units (the Séítah and Máaz formations), both of which contain evidence of later alteration by fluids including sulfate minerals. Results from the rover instruments Scanning Habitable Environments with Raman and Luminescence for Organics and Chemistry and Planetary Instrument for X-ray Lithochemistry reveal the presence of a mix of crystalline and amorphous hydrated Mg-sulfate minerals (both MgSO4·[3–5]H2O and possible MgSO4·H2O), and anhydrous Ca-sulfate minerals. The sulfate phases within each outcrop may have formed from single or multiple episodes of water activity, although several depositional events seem likely for the different units in the crater floor. Textural and chemical evidence suggest that the sulfate minerals most likely precipitated from a low temperature sulfate-rich fluid of moderate pH. The identification of approximately four waters puts a lower constraint on the hydration state of sulfate minerals in the shallow subsurface, which has implications for the martian hydrological budget. These sulfate minerals are key samples for future Mars sample return.

AB - Sulfur plays a major role in martian geochemistry and sulfate minerals are important repositories of water. However, their hydration states on Mars are poorly constrained. Therefore, understanding the hydration and distribution of sulfate minerals on Mars is important for understanding its geologic, hydrologic, and atmospheric evolution as well as its habitability potential. NASA's Perseverance rover is currently exploring the Noachian-age Jezero crater, which hosts a fan-delta system associated with a paleolake. The crater floor includes two igneous units (the Séítah and Máaz formations), both of which contain evidence of later alteration by fluids including sulfate minerals. Results from the rover instruments Scanning Habitable Environments with Raman and Luminescence for Organics and Chemistry and Planetary Instrument for X-ray Lithochemistry reveal the presence of a mix of crystalline and amorphous hydrated Mg-sulfate minerals (both MgSO4·[3–5]H2O and possible MgSO4·H2O), and anhydrous Ca-sulfate minerals. The sulfate phases within each outcrop may have formed from single or multiple episodes of water activity, although several depositional events seem likely for the different units in the crater floor. Textural and chemical evidence suggest that the sulfate minerals most likely precipitated from a low temperature sulfate-rich fluid of moderate pH. The identification of approximately four waters puts a lower constraint on the hydration state of sulfate minerals in the shallow subsurface, which has implications for the martian hydrological budget. These sulfate minerals are key samples for future Mars sample return.

KW - Mars

KW - PIXL

KW - Perseverance

KW - SHERLOC

KW - hydration

KW - sulfate

UR - https://www.scopus.com/pages/publications/85182815554

U2 - 10.1029/2023JE007989

DO - 10.1029/2023JE007989

M3 - Article

AN - SCOPUS:85182815554

SN - 2169-9097

VL - 129

JO - Journal of Geophysical Research: Planets

JF - Journal of Geophysical Research: Planets

IS - 1

M1 - e2023JE007989

ER -

Evidence of Sulfate-Rich Fluid Alteration in Jezero Crater Floor, Mars

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Keywords

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