Observations and preliminary science results from the first 100 sols of MSL Rover Environmental Monitoring Station ground temperature sensor measurements at Gale Crater

Victoria E. Hamilton; Ashwin R. Vasavada; Eduardo Sebastián; Manuel De La Torre Juárez; Miguel Ramos; Carlos Armiens; Raymond E. Arvidson; Isaías Carrasco; Philip R. Christensen; Miguel A. De Pablo; Walter Goetz; Javier Gõmez-Elvira; Mark T. Lemmon; Morten B. Madsen; Javier Martin-Torres; Jesús Martínez-Frías; Antonio Molina; Marisa C. Palucis; Scot C R Rafkin; Mark I. Richardson; R. Aileen Yingst; María-Paz Zorzano

doi:10.1002/2013JE004520

Observations and preliminary science results from the first 100 sols of MSL Rover Environmental Monitoring Station ground temperature sensor measurements at Gale Crater

Victoria E. Hamilton^*, Ashwin R. Vasavada, Eduardo Sebastián, Manuel De La Torre Juárez, Miguel Ramos, Carlos Armiens, Raymond E. Arvidson, Isaías Carrasco, Philip R. Christensen, Miguel A. De Pablo, Walter Goetz, Javier Gõmez-Elvira, Mark T. Lemmon, Morten B. Madsen, Javier Martin-Torres, Jesús Martínez-Frías, Antonio Molina, Marisa C. Palucis, Scot C R Rafkin, Mark I. RichardsonR. Aileen Yingst, María-Paz Zorzano

^*Corresponding author for this work

Geology and Geophysics

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Abstract

We describe preliminary results from the first 100 sols of ground temperature measurements along the Mars Science Laboratory's traverse from Bradbury Landing to Rocknest in Gale. The ground temperature data show long-term increases in mean temperature that are consistent with seasonal evolution. Deviations from expected temperature trends within the diurnal cycle are observed and may be attributed to rover and environmental effects. Fits to measured diurnal temperature amplitudes using a thermal model suggest that the observed surfaces have thermal inertias in the range of 265-375?J m-2 K-1 s-1/2, which are within the range of values determined from orbital measurements and are consistent with the inertias predicted from the observed particle sizes on the uppermost surface near the rover. Ground temperatures at Gale Crater appear to warm earlier and cool later than predicted by the model, suggesting that there are multiple unaccounted for physical conditions or processes in our models. Where the Mars Science Laboratory (MSL) descent engines removed a mobile layer of dust and fine sediments from over rockier material, the diurnal temperature profile is closer to that expected for a homogeneous surface, suggesting that the mobile materials on the uppermost surface may be partially responsible for the mismatch between observed temperatures and those predicted for materials having a single thermal inertia. Models of local stratigraphy also implicate thermophysical heterogeneity at the uppermost surface as a potential contributor to the observed diurnal temperature cycle. Key Points Diurnal ground temperatures vary with location Diurnal temperature curves are not well matched by a homogeneous thermal model GTS data are consistent with a varied stratigraphy and thermophysical properties.

Original language	English
Pages (from-to)	745-770
Number of pages	26
Journal	Journal of Geophysical Research
Volume	119
Issue number	4
Early online date	10 Apr 2014
DOIs	https://doi.org/10.1002/2013JE004520
Publication status	Published - Apr 2014

Keywords

ground temperature
Mars
thermal inertia
thermophysics

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Hamilton, V. E., Vasavada, A. R., Sebastián, E., Juárez, M. D. L. T., Ramos, M., Armiens, C., Arvidson, R. E., Carrasco, I., Christensen, P. R., Pablo, M. A. D., Goetz, W., Gõmez-Elvira, J., Lemmon, M. T., Madsen, M. B., Martin-Torres, J., Martínez-Frías, J., Molina, A., Palucis, M. C., Rafkin, S. C. R., ... Zorzano, M-P. (2014). Observations and preliminary science results from the first 100 sols of MSL Rover Environmental Monitoring Station ground temperature sensor measurements at Gale Crater. Journal of Geophysical Research, 119(4), 745-770. https://doi.org/10.1002/2013JE004520

Observations and preliminary science results from the first 100 sols of MSL Rover Environmental Monitoring Station ground temperature sensor measurements at Gale Crater. / Hamilton, Victoria E.; Vasavada, Ashwin R.; Sebastián, Eduardo et al.

In: Journal of Geophysical Research, Vol. 119, No. 4, 04.2014, p. 745-770.

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

Hamilton, VE, Vasavada, AR, Sebastián, E, Juárez, MDLT, Ramos, M, Armiens, C, Arvidson, RE, Carrasco, I, Christensen, PR, Pablo, MAD, Goetz, W, Gõmez-Elvira, J, Lemmon, MT, Madsen, MB, Martin-Torres, J, Martínez-Frías, J, Molina, A, Palucis, MC, Rafkin, SCR, Richardson, MI, Yingst, RA & Zorzano, M-P 2014, 'Observations and preliminary science results from the first 100 sols of MSL Rover Environmental Monitoring Station ground temperature sensor measurements at Gale Crater', Journal of Geophysical Research, vol. 119, no. 4, pp. 745-770. https://doi.org/10.1002/2013JE004520

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title = "Observations and preliminary science results from the first 100 sols of MSL Rover Environmental Monitoring Station ground temperature sensor measurements at Gale Crater",

abstract = "We describe preliminary results from the first 100 sols of ground temperature measurements along the Mars Science Laboratory's traverse from Bradbury Landing to Rocknest in Gale. The ground temperature data show long-term increases in mean temperature that are consistent with seasonal evolution. Deviations from expected temperature trends within the diurnal cycle are observed and may be attributed to rover and environmental effects. Fits to measured diurnal temperature amplitudes using a thermal model suggest that the observed surfaces have thermal inertias in the range of 265-375?J m-2 K-1 s-1/2, which are within the range of values determined from orbital measurements and are consistent with the inertias predicted from the observed particle sizes on the uppermost surface near the rover. Ground temperatures at Gale Crater appear to warm earlier and cool later than predicted by the model, suggesting that there are multiple unaccounted for physical conditions or processes in our models. Where the Mars Science Laboratory (MSL) descent engines removed a mobile layer of dust and fine sediments from over rockier material, the diurnal temperature profile is closer to that expected for a homogeneous surface, suggesting that the mobile materials on the uppermost surface may be partially responsible for the mismatch between observed temperatures and those predicted for materials having a single thermal inertia. Models of local stratigraphy also implicate thermophysical heterogeneity at the uppermost surface as a potential contributor to the observed diurnal temperature cycle. Key Points Diurnal ground temperatures vary with location Diurnal temperature curves are not well matched by a homogeneous thermal model GTS data are consistent with a varied stratigraphy and thermophysical properties.",

keywords = "ground temperature, Mars, thermal inertia, thermophysics",

author = "Hamilton, {Victoria E.} and Vasavada, {Ashwin R.} and Eduardo Sebasti{\'a}n and Ju{\'a}rez, {Manuel De La Torre} and Miguel Ramos and Carlos Armiens and Arvidson, {Raymond E.} and Isa{\'i}as Carrasco and Christensen, {Philip R.} and Pablo, {Miguel A. De} and Walter Goetz and Javier G{\~o}mez-Elvira and Lemmon, {Mark T.} and Madsen, {Morten B.} and Javier Martin-Torres and Jes{\'u}s Mart{\'i}nez-Fr{\'i}as and Antonio Molina and Palucis, {Marisa C.} and Rafkin, {Scot C R} and Richardson, {Mark I.} and Yingst, {R. Aileen} and Mar{\'i}a-Paz Zorzano",

note = "V.E.H. is supported by the Mars Science Laboratory and 2001 Mars Odyssey Participating Scientist Programs. E.S., C.A., M.R., I.C., J.G.‐E., M.A.D.P., J.M.‐T., and M.‐P.Z. are supported by the Economy and Competitivity Ministry (projects AYA2011‐25720 and AYA2012‐38707). A.V., M.T.L., and M.T.J. are supported by the Mars Science Laboratory project. W.G. acknowledges partial funding by the Deutsche Forschungsgemeinschaft (DFG grant GO 2288/1‐1). M.B.M. is supported by the Danish Council for Independent Research/Natural Sciences (FNU grant 0602‐02713B). We greatly appreciate all of the scientists and engineers who spent many years working to make the MSL mission such a success. We also thank the MSL Science Team for their support of the REMS investigation, and we deeply appreciate the REMS PULs and PDLs (who do the daily hard work of planning and validating REMS data, usually in the middle of the Spanish night). We are grateful to Tim Parker and Fred Calef at JPL for rapid updates to and information about the rover localization data. Others who have contributed their time and/or advice include Elena McCartney (MSSS), Larry Edwards (NASA Ames), the MSLICE team at JPL, Josh Bandfield (SSI), Hugh Kieffer (Celestial Reasonings), Than Putzig (SwRI), Bob Haberle (NASA Ames), F. Scott Anderson (SwRI), Chris Edwards (Caltech), Mike Smith (GSFC), Mike Wolff (SSI), Jonathan Hill (ASU), Kelly Bender (ASU), Dale Noss (ASU), and Kimm Murray (ASU). Last, but definitely not the least, we thank Josh Bandfield and an anonymous reviewer for thorough, constructive critiques that helped improve the manuscript.",

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doi = "10.1002/2013JE004520",

language = "English",

volume = "119",

pages = "745--770",

journal = "Journal of Geophysical Research",

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T1 - Observations and preliminary science results from the first 100 sols of MSL Rover Environmental Monitoring Station ground temperature sensor measurements at Gale Crater

AU - Hamilton, Victoria E.

AU - Vasavada, Ashwin R.

AU - Sebastián, Eduardo

AU - Juárez, Manuel De La Torre

AU - Ramos, Miguel

AU - Armiens, Carlos

AU - Arvidson, Raymond E.

AU - Carrasco, Isaías

AU - Christensen, Philip R.

AU - Pablo, Miguel A. De

AU - Goetz, Walter

AU - Gõmez-Elvira, Javier

AU - Lemmon, Mark T.

AU - Madsen, Morten B.

AU - Martin-Torres, Javier

AU - Martínez-Frías, Jesús

AU - Molina, Antonio

AU - Palucis, Marisa C.

AU - Rafkin, Scot C R

AU - Richardson, Mark I.

AU - Yingst, R. Aileen

AU - Zorzano, María-Paz

N1 - V.E.H. is supported by the Mars Science Laboratory and 2001 Mars Odyssey Participating Scientist Programs. E.S., C.A., M.R., I.C., J.G.‐E., M.A.D.P., J.M.‐T., and M.‐P.Z. are supported by the Economy and Competitivity Ministry (projects AYA2011‐25720 and AYA2012‐38707). A.V., M.T.L., and M.T.J. are supported by the Mars Science Laboratory project. W.G. acknowledges partial funding by the Deutsche Forschungsgemeinschaft (DFG grant GO 2288/1‐1). M.B.M. is supported by the Danish Council for Independent Research/Natural Sciences (FNU grant 0602‐02713B). We greatly appreciate all of the scientists and engineers who spent many years working to make the MSL mission such a success. We also thank the MSL Science Team for their support of the REMS investigation, and we deeply appreciate the REMS PULs and PDLs (who do the daily hard work of planning and validating REMS data, usually in the middle of the Spanish night). We are grateful to Tim Parker and Fred Calef at JPL for rapid updates to and information about the rover localization data. Others who have contributed their time and/or advice include Elena McCartney (MSSS), Larry Edwards (NASA Ames), the MSLICE team at JPL, Josh Bandfield (SSI), Hugh Kieffer (Celestial Reasonings), Than Putzig (SwRI), Bob Haberle (NASA Ames), F. Scott Anderson (SwRI), Chris Edwards (Caltech), Mike Smith (GSFC), Mike Wolff (SSI), Jonathan Hill (ASU), Kelly Bender (ASU), Dale Noss (ASU), and Kimm Murray (ASU). Last, but definitely not the least, we thank Josh Bandfield and an anonymous reviewer for thorough, constructive critiques that helped improve the manuscript.

PY - 2014/4

Y1 - 2014/4

N2 - We describe preliminary results from the first 100 sols of ground temperature measurements along the Mars Science Laboratory's traverse from Bradbury Landing to Rocknest in Gale. The ground temperature data show long-term increases in mean temperature that are consistent with seasonal evolution. Deviations from expected temperature trends within the diurnal cycle are observed and may be attributed to rover and environmental effects. Fits to measured diurnal temperature amplitudes using a thermal model suggest that the observed surfaces have thermal inertias in the range of 265-375?J m-2 K-1 s-1/2, which are within the range of values determined from orbital measurements and are consistent with the inertias predicted from the observed particle sizes on the uppermost surface near the rover. Ground temperatures at Gale Crater appear to warm earlier and cool later than predicted by the model, suggesting that there are multiple unaccounted for physical conditions or processes in our models. Where the Mars Science Laboratory (MSL) descent engines removed a mobile layer of dust and fine sediments from over rockier material, the diurnal temperature profile is closer to that expected for a homogeneous surface, suggesting that the mobile materials on the uppermost surface may be partially responsible for the mismatch between observed temperatures and those predicted for materials having a single thermal inertia. Models of local stratigraphy also implicate thermophysical heterogeneity at the uppermost surface as a potential contributor to the observed diurnal temperature cycle. Key Points Diurnal ground temperatures vary with location Diurnal temperature curves are not well matched by a homogeneous thermal model GTS data are consistent with a varied stratigraphy and thermophysical properties.

AB - We describe preliminary results from the first 100 sols of ground temperature measurements along the Mars Science Laboratory's traverse from Bradbury Landing to Rocknest in Gale. The ground temperature data show long-term increases in mean temperature that are consistent with seasonal evolution. Deviations from expected temperature trends within the diurnal cycle are observed and may be attributed to rover and environmental effects. Fits to measured diurnal temperature amplitudes using a thermal model suggest that the observed surfaces have thermal inertias in the range of 265-375?J m-2 K-1 s-1/2, which are within the range of values determined from orbital measurements and are consistent with the inertias predicted from the observed particle sizes on the uppermost surface near the rover. Ground temperatures at Gale Crater appear to warm earlier and cool later than predicted by the model, suggesting that there are multiple unaccounted for physical conditions or processes in our models. Where the Mars Science Laboratory (MSL) descent engines removed a mobile layer of dust and fine sediments from over rockier material, the diurnal temperature profile is closer to that expected for a homogeneous surface, suggesting that the mobile materials on the uppermost surface may be partially responsible for the mismatch between observed temperatures and those predicted for materials having a single thermal inertia. Models of local stratigraphy also implicate thermophysical heterogeneity at the uppermost surface as a potential contributor to the observed diurnal temperature cycle. Key Points Diurnal ground temperatures vary with location Diurnal temperature curves are not well matched by a homogeneous thermal model GTS data are consistent with a varied stratigraphy and thermophysical properties.

KW - ground temperature

KW - Mars

KW - thermal inertia

KW - thermophysics

U2 - 10.1002/2013JE004520

DO - 10.1002/2013JE004520

M3 - Article

VL - 119

SP - 745

EP - 770

JO - Journal of Geophysical Research

JF - Journal of Geophysical Research

SN - 0148-0227

IS - 4

ER -

Observations and preliminary science results from the first 100 sols of MSL Rover Environmental Monitoring Station ground temperature sensor measurements at Gale Crater

Abstract

Keywords

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