The dual nature of the martian crust: Young lavas and old clastic materials

Joshua L. Bandfield; Christopher S. Edwards; David R. Montgomery; Brittany D. Brand

doi:10.1016/j.icarus.2012.10.023

The dual nature of the martian crust: Young lavas and old clastic materials

Joshua L. Bandfield, Christopher S. Edwards, David R. Montgomery, Brittany D. Brand

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

56 Scopus citations

Abstract

Visible and thermal infrared spacecraft datasets are used to gain insight into the nature of the surface materials and upper martian crust, revealing a distinct transition in the physical properties of martian crustal materials that occurred during the Hesperian era. Contrary to a prevailing view of the martian crust as primarily composed of lava flows, we find that most older regions of Mars have morphological and thermophysical properties consistent with poorly consolidated fine-particulate materials that may have a volcaniclastic origin. By contrast, younger surfaces contain blocky materials and thermophysical properties consistent with effusive lava flows. Explosive volcanism is likely to have been dominant on early Mars and these findings have implications for the evolution of the volatile content of the crust and mantle and subsequent development of the surface morphology. This dual nature of the crust appears to be a defining characteristic of martian history.

Original language	English
Pages (from-to)	188-199
Number of pages	12
Journal	Icarus
Volume	222
Issue number	1
DOIs	https://doi.org/10.1016/j.icarus.2012.10.023
State	Published - Jan 2013
Externally published	Yes

Keywords

Geological processes
Infrared observations
Mars, Surface
Regoliths
Terrestrial planets

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10.1016/j.icarus.2012.10.023

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title = "The dual nature of the martian crust: Young lavas and old clastic materials",

abstract = "Visible and thermal infrared spacecraft datasets are used to gain insight into the nature of the surface materials and upper martian crust, revealing a distinct transition in the physical properties of martian crustal materials that occurred during the Hesperian era. Contrary to a prevailing view of the martian crust as primarily composed of lava flows, we find that most older regions of Mars have morphological and thermophysical properties consistent with poorly consolidated fine-particulate materials that may have a volcaniclastic origin. By contrast, younger surfaces contain blocky materials and thermophysical properties consistent with effusive lava flows. Explosive volcanism is likely to have been dominant on early Mars and these findings have implications for the evolution of the volatile content of the crust and mantle and subsequent development of the surface morphology. This dual nature of the crust appears to be a defining characteristic of martian history.",

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AU - Bandfield, Joshua L.

AU - Edwards, Christopher S.

AU - Montgomery, David R.

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AB - Visible and thermal infrared spacecraft datasets are used to gain insight into the nature of the surface materials and upper martian crust, revealing a distinct transition in the physical properties of martian crustal materials that occurred during the Hesperian era. Contrary to a prevailing view of the martian crust as primarily composed of lava flows, we find that most older regions of Mars have morphological and thermophysical properties consistent with poorly consolidated fine-particulate materials that may have a volcaniclastic origin. By contrast, younger surfaces contain blocky materials and thermophysical properties consistent with effusive lava flows. Explosive volcanism is likely to have been dominant on early Mars and these findings have implications for the evolution of the volatile content of the crust and mantle and subsequent development of the surface morphology. This dual nature of the crust appears to be a defining characteristic of martian history.

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The dual nature of the martian crust: Young lavas and old clastic materials

Abstract

Keywords

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