Spectral Characterization of Bennu Analogs Using PASCALE: A New Experimental Set-Up for Simulating the Near-Surface Conditions of Airless Bodies

K. L. Donaldson Hanna; N. E. Bowles; T. J. Warren; V. E. Hamilton; D. L. Schrader; T. J. McCoy; J. Temple; A. Clack; S. Calcutt; D. S. Lauretta

doi:10.1029/2020JE006624

Spectral Characterization of Bennu Analogs Using PASCALE: A New Experimental Set-Up for Simulating the Near-Surface Conditions of Airless Bodies

K. L. Donaldson Hanna, N. E. Bowles, T. J. Warren, V. E. Hamilton, D. L. Schrader, T. J. McCoy, J. Temple, A. Clack, S. Calcutt, D. S. Lauretta

Meteorite Studies, Center for

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

7 Scopus citations

Abstract

We describe the capabilities, radiometric stability, and calibration of a custom vacuum environment chamber capable of simulating the near-surface conditions of airless bodies. Here we demonstrate the collection of spectral measurements of a suite of fine particulate asteroid analogs made using the Planetary Analogue Surface Chamber for Asteroid and Lunar Environments (PASCALE) under conditions like those found on Earth and on airless bodies. The sample suite includes anhydrous and hydrated physical mixtures, and chondritic meteorites (CM, CI, CV, CR, and L5) previously characterized under Earth- and asteroid-like conditions. And for the first time, we measure the terrestrial and extra-terrestrial mineral end members used in the olivine- and phyllosilicate-dominated physical mixtures under the same conditions as the mixtures and meteorites allowing us better understand how minerals combine spectrally when mixed intimately. Our measurements highlight the sensitivity of thermal infrared emissivity spectra to small amounts of low albedo materials and the composition of the sample materials. As the albedo of the sample decreases, we observe smaller differences between Earth- and asteroid-like spectra, which results from a reduced thermal gradient in the upper hundreds of microns in the sample. These spectral measurements can be compared to thermal infrared emissivity spectra of asteroid (101955) Bennu's surface in regions where similarly fine particulate materials may be observed to infer surface compositions.

Original language	English (US)
Article number	e2020JE006624
Journal	Journal of Geophysical Research: Planets
Volume	126
Issue number	2
DOIs	https://doi.org/10.1029/2020JE006624
State	Published - Feb 2021

Keywords

Bennu
airless bodies
laboratory
spectroscopy
thermal infrared

ASJC Scopus subject areas

Geochemistry and Petrology
Geophysics
Earth and Planetary Sciences (miscellaneous)
Space and Planetary Science

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10.1029/2020JE006624

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Donaldson Hanna, K. L., Bowles, N. E., Warren, T. J., Hamilton, V. E., Schrader, D. L., McCoy, T. J., Temple, J., Clack, A., Calcutt, S., & Lauretta, D. S. (2021). Spectral Characterization of Bennu Analogs Using PASCALE: A New Experimental Set-Up for Simulating the Near-Surface Conditions of Airless Bodies. Journal of Geophysical Research: Planets, 126(2), Article e2020JE006624. https://doi.org/10.1029/2020JE006624

Donaldson Hanna, KL, Bowles, NE, Warren, TJ, Hamilton, VE, Schrader, DL, McCoy, TJ, Temple, J, Clack, A, Calcutt, S & Lauretta, DS 2021, 'Spectral Characterization of Bennu Analogs Using PASCALE: A New Experimental Set-Up for Simulating the Near-Surface Conditions of Airless Bodies', Journal of Geophysical Research: Planets, vol. 126, no. 2, e2020JE006624. https://doi.org/10.1029/2020JE006624

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title = "Spectral Characterization of Bennu Analogs Using PASCALE: A New Experimental Set-Up for Simulating the Near-Surface Conditions of Airless Bodies",

abstract = "We describe the capabilities, radiometric stability, and calibration of a custom vacuum environment chamber capable of simulating the near-surface conditions of airless bodies. Here we demonstrate the collection of spectral measurements of a suite of fine particulate asteroid analogs made using the Planetary Analogue Surface Chamber for Asteroid and Lunar Environments (PASCALE) under conditions like those found on Earth and on airless bodies. The sample suite includes anhydrous and hydrated physical mixtures, and chondritic meteorites (CM, CI, CV, CR, and L5) previously characterized under Earth- and asteroid-like conditions. And for the first time, we measure the terrestrial and extra-terrestrial mineral end members used in the olivine- and phyllosilicate-dominated physical mixtures under the same conditions as the mixtures and meteorites allowing us better understand how minerals combine spectrally when mixed intimately. Our measurements highlight the sensitivity of thermal infrared emissivity spectra to small amounts of low albedo materials and the composition of the sample materials. As the albedo of the sample decreases, we observe smaller differences between Earth- and asteroid-like spectra, which results from a reduced thermal gradient in the upper hundreds of microns in the sample. These spectral measurements can be compared to thermal infrared emissivity spectra of asteroid (101955) Bennu's surface in regions where similarly fine particulate materials may be observed to infer surface compositions.",

keywords = "Bennu, airless bodies, laboratory, spectroscopy, thermal infrared",

author = "{Donaldson Hanna}, {K. L.} and Bowles, {N. E.} and Warren, {T. J.} and Hamilton, {V. E.} and Schrader, {D. L.} and McCoy, {T. J.} and J. Temple and A. Clack and S. Calcutt and Lauretta, {D. S.}",

note = "Funding Information: We thank the reviewers, Melissa Lane and Karen Stockstill‐Cahill, for their thorough and thoughtful edits. This manuscript is based upon work supported by the National Aeronautics and Space Administration under Contract NNM10AA11C issued through the New Frontiers Program. We thank the Smithsonian Institution, NSF, NASA, Paul Pohwat (Smithsonian), and the Arizona State University Center for Meteorite Studies Meteorite Collection for supplying the samples that were necessary for this work. The US Antarctic meteorite samples are recovered by the Antarctic Search for Meteorites (ANSMET) program, which has been funded by NSF and NASA, and characterized and curated by the Department of Mineral Sciences of the Smithsonian Institution and Astromaterials Curation Office at NASA Johnson Space Center. Donaldson Hanna thanks the Leverhulme Trust for their support through a postdoctoral fellowship and the UK Space Agency for their support through an Aurora Research Fellowship. Donaldson Hanna, Bowles, Warren, Temple, Clack, and Calcutt thank the UK Science and Technology Facilities Council for supporting the University of Oxford's Planetary Spectroscopy Facility. Funding Information: We thank the reviewers, Melissa Lane and Karen Stockstill-Cahill, for their thorough and thoughtful edits. This manuscript is based upon work supported by the National Aeronautics and Space Administration under Contract NNM10AA11C issued through the New Frontiers Program. We thank the Smithsonian Institution, NSF, NASA, Paul Pohwat (Smithsonian), and the Arizona State University Center for Meteorite Studies Meteorite Collection for supplying the samples that were necessary for this work. The US Antarctic meteorite samples are recovered by the Antarctic Search for Meteorites (ANSMET) program, which has been funded by NSF and NASA, and characterized and curated by the Department of Mineral Sciences of the Smithsonian Institution and Astromaterials Curation Office at NASA Johnson Space Center. Donaldson Hanna thanks the Leverhulme Trust for their support through a postdoctoral fellowship and the UK Space Agency for their support through an Aurora Research Fellowship. Donaldson Hanna, Bowles, Warren, Temple, Clack, and Calcutt thank the UK Science and Technology Facilities Council for supporting the University of Oxford's Planetary Spectroscopy Facility. Publisher Copyright: {\textcopyright} 2020. The Authors.",

year = "2021",

month = feb,

doi = "10.1029/2020JE006624",

language = "English (US)",

volume = "126",

journal = "Journal of Geophysical Research: Planets",

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T2 - A New Experimental Set-Up for Simulating the Near-Surface Conditions of Airless Bodies

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AU - Bowles, N. E.

AU - Warren, T. J.

AU - Hamilton, V. E.

AU - Schrader, D. L.

AU - McCoy, T. J.

AU - Temple, J.

AU - Clack, A.

AU - Calcutt, S.

AU - Lauretta, D. S.

N1 - Funding Information: We thank the reviewers, Melissa Lane and Karen Stockstill‐Cahill, for their thorough and thoughtful edits. This manuscript is based upon work supported by the National Aeronautics and Space Administration under Contract NNM10AA11C issued through the New Frontiers Program. We thank the Smithsonian Institution, NSF, NASA, Paul Pohwat (Smithsonian), and the Arizona State University Center for Meteorite Studies Meteorite Collection for supplying the samples that were necessary for this work. The US Antarctic meteorite samples are recovered by the Antarctic Search for Meteorites (ANSMET) program, which has been funded by NSF and NASA, and characterized and curated by the Department of Mineral Sciences of the Smithsonian Institution and Astromaterials Curation Office at NASA Johnson Space Center. Donaldson Hanna thanks the Leverhulme Trust for their support through a postdoctoral fellowship and the UK Space Agency for their support through an Aurora Research Fellowship. Donaldson Hanna, Bowles, Warren, Temple, Clack, and Calcutt thank the UK Science and Technology Facilities Council for supporting the University of Oxford's Planetary Spectroscopy Facility. Funding Information: We thank the reviewers, Melissa Lane and Karen Stockstill-Cahill, for their thorough and thoughtful edits. This manuscript is based upon work supported by the National Aeronautics and Space Administration under Contract NNM10AA11C issued through the New Frontiers Program. We thank the Smithsonian Institution, NSF, NASA, Paul Pohwat (Smithsonian), and the Arizona State University Center for Meteorite Studies Meteorite Collection for supplying the samples that were necessary for this work. The US Antarctic meteorite samples are recovered by the Antarctic Search for Meteorites (ANSMET) program, which has been funded by NSF and NASA, and characterized and curated by the Department of Mineral Sciences of the Smithsonian Institution and Astromaterials Curation Office at NASA Johnson Space Center. Donaldson Hanna thanks the Leverhulme Trust for their support through a postdoctoral fellowship and the UK Space Agency for their support through an Aurora Research Fellowship. Donaldson Hanna, Bowles, Warren, Temple, Clack, and Calcutt thank the UK Science and Technology Facilities Council for supporting the University of Oxford's Planetary Spectroscopy Facility. Publisher Copyright: © 2020. The Authors.

PY - 2021/2

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N2 - We describe the capabilities, radiometric stability, and calibration of a custom vacuum environment chamber capable of simulating the near-surface conditions of airless bodies. Here we demonstrate the collection of spectral measurements of a suite of fine particulate asteroid analogs made using the Planetary Analogue Surface Chamber for Asteroid and Lunar Environments (PASCALE) under conditions like those found on Earth and on airless bodies. The sample suite includes anhydrous and hydrated physical mixtures, and chondritic meteorites (CM, CI, CV, CR, and L5) previously characterized under Earth- and asteroid-like conditions. And for the first time, we measure the terrestrial and extra-terrestrial mineral end members used in the olivine- and phyllosilicate-dominated physical mixtures under the same conditions as the mixtures and meteorites allowing us better understand how minerals combine spectrally when mixed intimately. Our measurements highlight the sensitivity of thermal infrared emissivity spectra to small amounts of low albedo materials and the composition of the sample materials. As the albedo of the sample decreases, we observe smaller differences between Earth- and asteroid-like spectra, which results from a reduced thermal gradient in the upper hundreds of microns in the sample. These spectral measurements can be compared to thermal infrared emissivity spectra of asteroid (101955) Bennu's surface in regions where similarly fine particulate materials may be observed to infer surface compositions.

AB - We describe the capabilities, radiometric stability, and calibration of a custom vacuum environment chamber capable of simulating the near-surface conditions of airless bodies. Here we demonstrate the collection of spectral measurements of a suite of fine particulate asteroid analogs made using the Planetary Analogue Surface Chamber for Asteroid and Lunar Environments (PASCALE) under conditions like those found on Earth and on airless bodies. The sample suite includes anhydrous and hydrated physical mixtures, and chondritic meteorites (CM, CI, CV, CR, and L5) previously characterized under Earth- and asteroid-like conditions. And for the first time, we measure the terrestrial and extra-terrestrial mineral end members used in the olivine- and phyllosilicate-dominated physical mixtures under the same conditions as the mixtures and meteorites allowing us better understand how minerals combine spectrally when mixed intimately. Our measurements highlight the sensitivity of thermal infrared emissivity spectra to small amounts of low albedo materials and the composition of the sample materials. As the albedo of the sample decreases, we observe smaller differences between Earth- and asteroid-like spectra, which results from a reduced thermal gradient in the upper hundreds of microns in the sample. These spectral measurements can be compared to thermal infrared emissivity spectra of asteroid (101955) Bennu's surface in regions where similarly fine particulate materials may be observed to infer surface compositions.

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KW - airless bodies

KW - laboratory

KW - spectroscopy

KW - thermal infrared

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Spectral Characterization of Bennu Analogs Using PASCALE: A New Experimental Set-Up for Simulating the Near-Surface Conditions of Airless Bodies

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Keywords

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