Mineralogic and compositional properties of Martian soil and dust: Results from Mars Pathfinder

J. F. Bell; H. Y. Mcsween; J. A. Crisp; R. V. Morris; S. L. Murchie; N. T. Bridges; J. R. Johnson; D. T. Britt; M. P. Golombek; H. J. Moore; A. Ghosh; J. L. Bishop; R. C. Anderson; J. Brückner; T. Economou; J. P. Greenwood; H. P. Gunnlaugsson; R. M. Hargraves; S. Hviid; J. M. Knudsen; M. B. Madsen; R. Reid; R. Rieder; L. Soderblom

doi:10.1029/1999JE001060

Mineralogic and compositional properties of Martian soil and dust: Results from Mars Pathfinder

J. F. Bell, H. Y. Mcsween, J. A. Crisp, R. V. Morris, S. L. Murchie, N. T. Bridges, J. R. Johnson, D. T. Britt, M. P. Golombek, H. J. Moore, A. Ghosh, J. L. Bishop, R. C. Anderson, J. Brückner, T. Economou, J. P. Greenwood, H. P. Gunnlaugsson, R. M. Hargraves, S. Hviid, J. M. KnudsenM. B. Madsen, R. Reid, R. Rieder, L. Soderblom

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

265 Scopus citations

Abstract

Mars Pathfinder obtained multispectral, elemental, magnetic, and physical measurements of soil and dust at the Sagan Memorial Station during the course of its 83 sol mission. We describe initial results from these measurements, concentrating on multispectral and elemental data, and use these data, along with previous Viking, SNC meteorite, and telescopic results, to help constrain the origin and evolution of Martian soil and dust. We find that soils and dust can be divided into at least eight distinct spectral units, based on parameterization of Imager for Mars Pathfinder (IMP) 400 to 1000 nm multispectral images. The most distinctive spectral parameters for soils and dust are the reflectivity in the red, the red/blue reflectivity ratio, the near-IR spectral slope, and the strength of the 800 to 1000 nm absorption feature. Most of the Pathfinder spectra are consistent with the presence of poorly crystalline or nanophase ferric oxide(s), sometimes mixed with small but varying degrees of well-crystalline ferric and ferrous phases. Darker soil units appear to be coarser-grained, compacted, and/or mixed with a larger amount of dark ferrous materials relative to bright soils. Nanophase goethite, akaganeite, schwertmannite, and maghemite are leading candidates for the origin of the absorption centered near 900 nm in IMP spectra. The ferrous component in the soil cannot be well-constrained based on IMP data. Alpha proton X-ray spectrometer (APXS) measurements of six soil units show little variability within the landing site and show remarkable overall similarity to the average Viking-derived soil elemental composition. Differences exist between Viking and Pathfinder soils, however, including significantly higher S and Cl abundances and lower Si abundances in Viking soils and the lack of a correlation between Ti and Fe in Pathfinder soils. No significant linear correlations were observed between IMP spectral properties and APXS elemental chemistry. Attempts at constraining the mineralogy of soils and dust using normative calculations involving mixtures of smectites and silicate and oxide minerals did not yield physically acceptable solutions. We attempted to use the Pathfinder results to constrain a number of putative soil and dust formation scenarios, including palagonitization and acid-fog weathering. While the Pathfinder soils cannot be chemically linked to the Pathfinder rocks by palagonitization, this study and McSween et al. [1999] suggest that palagonitic alteration of a Martian basaltic rock, plus mixture with a minor component of locally derived andesitic rock fragments, could be consistent with the observed soil APXS and IMP properties.

Original language	English (US)
Article number	1999JE001060
Pages (from-to)	1721-1755
Number of pages	35
Journal	Journal of Geophysical Research: Planets
Volume	105
Issue number	E1
DOIs	https://doi.org/10.1029/1999JE001060
State	Published - 2000
Externally published	Yes

ASJC Scopus subject areas

Geochemistry and Petrology
Geophysics
Earth and Planetary Sciences (miscellaneous)
Space and Planetary Science
Atmospheric Science
Astronomy and Astrophysics
Oceanography

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10.1029/1999JE001060

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Bell, J. F., Mcsween, H. Y., Crisp, J. A., Morris, R. V., Murchie, S. L., Bridges, N. T., Johnson, J. R., Britt, D. T., Golombek, M. P., Moore, H. J., Ghosh, A., Bishop, J. L., Anderson, R. C., Brückner, J., Economou, T., Greenwood, J. P., Gunnlaugsson, H. P., Hargraves, R. M., Hviid, S., ... Soderblom, L. (2000). Mineralogic and compositional properties of Martian soil and dust: Results from Mars Pathfinder. Journal of Geophysical Research: Planets, 105(E1), 1721-1755. Article 1999JE001060. https://doi.org/10.1029/1999JE001060

Bell, JF, Mcsween, HY, Crisp, JA, Morris, RV, Murchie, SL, Bridges, NT, Johnson, JR, Britt, DT, Golombek, MP, Moore, HJ, Ghosh, A, Bishop, JL, Anderson, RC, Brückner, J, Economou, T, Greenwood, JP, Gunnlaugsson, HP, Hargraves, RM, Hviid, S, Knudsen, JM, Madsen, MB, Reid, R, Rieder, R & Soderblom, L 2000, 'Mineralogic and compositional properties of Martian soil and dust: Results from Mars Pathfinder', Journal of Geophysical Research: Planets, vol. 105, no. E1, 1999JE001060, pp. 1721-1755. https://doi.org/10.1029/1999JE001060

@article{f132f81e8afb43dfaea4a0de0220d979,

title = "Mineralogic and compositional properties of Martian soil and dust: Results from Mars Pathfinder",

abstract = "Mars Pathfinder obtained multispectral, elemental, magnetic, and physical measurements of soil and dust at the Sagan Memorial Station during the course of its 83 sol mission. We describe initial results from these measurements, concentrating on multispectral and elemental data, and use these data, along with previous Viking, SNC meteorite, and telescopic results, to help constrain the origin and evolution of Martian soil and dust. We find that soils and dust can be divided into at least eight distinct spectral units, based on parameterization of Imager for Mars Pathfinder (IMP) 400 to 1000 nm multispectral images. The most distinctive spectral parameters for soils and dust are the reflectivity in the red, the red/blue reflectivity ratio, the near-IR spectral slope, and the strength of the 800 to 1000 nm absorption feature. Most of the Pathfinder spectra are consistent with the presence of poorly crystalline or nanophase ferric oxide(s), sometimes mixed with small but varying degrees of well-crystalline ferric and ferrous phases. Darker soil units appear to be coarser-grained, compacted, and/or mixed with a larger amount of dark ferrous materials relative to bright soils. Nanophase goethite, akaganeite, schwertmannite, and maghemite are leading candidates for the origin of the absorption centered near 900 nm in IMP spectra. The ferrous component in the soil cannot be well-constrained based on IMP data. Alpha proton X-ray spectrometer (APXS) measurements of six soil units show little variability within the landing site and show remarkable overall similarity to the average Viking-derived soil elemental composition. Differences exist between Viking and Pathfinder soils, however, including significantly higher S and Cl abundances and lower Si abundances in Viking soils and the lack of a correlation between Ti and Fe in Pathfinder soils. No significant linear correlations were observed between IMP spectral properties and APXS elemental chemistry. Attempts at constraining the mineralogy of soils and dust using normative calculations involving mixtures of smectites and silicate and oxide minerals did not yield physically acceptable solutions. We attempted to use the Pathfinder results to constrain a number of putative soil and dust formation scenarios, including palagonitization and acid-fog weathering. While the Pathfinder soils cannot be chemically linked to the Pathfinder rocks by palagonitization, this study and McSween et al. [1999] suggest that palagonitic alteration of a Martian basaltic rock, plus mixture with a minor component of locally derived andesitic rock fragments, could be consistent with the observed soil APXS and IMP properties.",

author = "Bell, {J. F.} and Mcsween, {H. Y.} and Crisp, {J. A.} and Morris, {R. V.} and Murchie, {S. L.} and Bridges, {N. T.} and Johnson, {J. R.} and Britt, {D. T.} and Golombek, {M. P.} and Moore, {H. J.} and A. Ghosh and Bishop, {J. L.} and Anderson, {R. C.} and J. Br{\"u}ckner and T. Economou and Greenwood, {J. P.} and Gunnlaugsson, {H. P.} and Hargraves, {R. M.} and S. Hviid and Knudsen, {J. M.} and Madsen, {M. B.} and R. Reid and R. Rieder and L. Soderblom",

year = "2000",

doi = "10.1029/1999JE001060",

language = "English (US)",

volume = "105",

pages = "1721--1755",

journal = "Journal of Geophysical Research: Planets",

issn = "0148-0227",

publisher = "Wiley-Blackwell Publishing Ltd",

number = "E1",

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TY - JOUR

T1 - Mineralogic and compositional properties of Martian soil and dust

T2 - Results from Mars Pathfinder

AU - Bell, J. F.

AU - Mcsween, H. Y.

AU - Crisp, J. A.

AU - Morris, R. V.

AU - Murchie, S. L.

AU - Bridges, N. T.

AU - Johnson, J. R.

AU - Britt, D. T.

AU - Golombek, M. P.

AU - Moore, H. J.

AU - Ghosh, A.

AU - Bishop, J. L.

AU - Anderson, R. C.

AU - Brückner, J.

AU - Economou, T.

AU - Greenwood, J. P.

AU - Gunnlaugsson, H. P.

AU - Hargraves, R. M.

AU - Hviid, S.

AU - Knudsen, J. M.

AU - Madsen, M. B.

AU - Reid, R.

AU - Rieder, R.

AU - Soderblom, L.

PY - 2000

Y1 - 2000

N2 - Mars Pathfinder obtained multispectral, elemental, magnetic, and physical measurements of soil and dust at the Sagan Memorial Station during the course of its 83 sol mission. We describe initial results from these measurements, concentrating on multispectral and elemental data, and use these data, along with previous Viking, SNC meteorite, and telescopic results, to help constrain the origin and evolution of Martian soil and dust. We find that soils and dust can be divided into at least eight distinct spectral units, based on parameterization of Imager for Mars Pathfinder (IMP) 400 to 1000 nm multispectral images. The most distinctive spectral parameters for soils and dust are the reflectivity in the red, the red/blue reflectivity ratio, the near-IR spectral slope, and the strength of the 800 to 1000 nm absorption feature. Most of the Pathfinder spectra are consistent with the presence of poorly crystalline or nanophase ferric oxide(s), sometimes mixed with small but varying degrees of well-crystalline ferric and ferrous phases. Darker soil units appear to be coarser-grained, compacted, and/or mixed with a larger amount of dark ferrous materials relative to bright soils. Nanophase goethite, akaganeite, schwertmannite, and maghemite are leading candidates for the origin of the absorption centered near 900 nm in IMP spectra. The ferrous component in the soil cannot be well-constrained based on IMP data. Alpha proton X-ray spectrometer (APXS) measurements of six soil units show little variability within the landing site and show remarkable overall similarity to the average Viking-derived soil elemental composition. Differences exist between Viking and Pathfinder soils, however, including significantly higher S and Cl abundances and lower Si abundances in Viking soils and the lack of a correlation between Ti and Fe in Pathfinder soils. No significant linear correlations were observed between IMP spectral properties and APXS elemental chemistry. Attempts at constraining the mineralogy of soils and dust using normative calculations involving mixtures of smectites and silicate and oxide minerals did not yield physically acceptable solutions. We attempted to use the Pathfinder results to constrain a number of putative soil and dust formation scenarios, including palagonitization and acid-fog weathering. While the Pathfinder soils cannot be chemically linked to the Pathfinder rocks by palagonitization, this study and McSween et al. [1999] suggest that palagonitic alteration of a Martian basaltic rock, plus mixture with a minor component of locally derived andesitic rock fragments, could be consistent with the observed soil APXS and IMP properties.

AB - Mars Pathfinder obtained multispectral, elemental, magnetic, and physical measurements of soil and dust at the Sagan Memorial Station during the course of its 83 sol mission. We describe initial results from these measurements, concentrating on multispectral and elemental data, and use these data, along with previous Viking, SNC meteorite, and telescopic results, to help constrain the origin and evolution of Martian soil and dust. We find that soils and dust can be divided into at least eight distinct spectral units, based on parameterization of Imager for Mars Pathfinder (IMP) 400 to 1000 nm multispectral images. The most distinctive spectral parameters for soils and dust are the reflectivity in the red, the red/blue reflectivity ratio, the near-IR spectral slope, and the strength of the 800 to 1000 nm absorption feature. Most of the Pathfinder spectra are consistent with the presence of poorly crystalline or nanophase ferric oxide(s), sometimes mixed with small but varying degrees of well-crystalline ferric and ferrous phases. Darker soil units appear to be coarser-grained, compacted, and/or mixed with a larger amount of dark ferrous materials relative to bright soils. Nanophase goethite, akaganeite, schwertmannite, and maghemite are leading candidates for the origin of the absorption centered near 900 nm in IMP spectra. The ferrous component in the soil cannot be well-constrained based on IMP data. Alpha proton X-ray spectrometer (APXS) measurements of six soil units show little variability within the landing site and show remarkable overall similarity to the average Viking-derived soil elemental composition. Differences exist between Viking and Pathfinder soils, however, including significantly higher S and Cl abundances and lower Si abundances in Viking soils and the lack of a correlation between Ti and Fe in Pathfinder soils. No significant linear correlations were observed between IMP spectral properties and APXS elemental chemistry. Attempts at constraining the mineralogy of soils and dust using normative calculations involving mixtures of smectites and silicate and oxide minerals did not yield physically acceptable solutions. We attempted to use the Pathfinder results to constrain a number of putative soil and dust formation scenarios, including palagonitization and acid-fog weathering. While the Pathfinder soils cannot be chemically linked to the Pathfinder rocks by palagonitization, this study and McSween et al. [1999] suggest that palagonitic alteration of a Martian basaltic rock, plus mixture with a minor component of locally derived andesitic rock fragments, could be consistent with the observed soil APXS and IMP properties.

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Mineralogic and compositional properties of Martian soil and dust: Results from Mars Pathfinder

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