LRO-LAMP detection of geologically young craters within lunar permanently shaded regions

Kathleen E. Mandt; Thomas K. Greathouse; Kurt D. Retherford; G. Randall Gladstone; Andrew P. Jordan; Myriam Lemelin; Steven D. Koeber; Ernest Bowman-Cisneros; G. Wesley Patterson; Mark Robinson; Paul G. Lucey; Amanda R. Hendrix; Dana Hurley; Angela M. Stickle; Wayne Pryor

doi:10.1016/j.icarus.2015.07.031

LRO-LAMP detection of geologically young craters within lunar permanently shaded regions

Kathleen E. Mandt, Thomas K. Greathouse, Kurt D. Retherford, G. Randall Gladstone, Andrew P. Jordan, Myriam Lemelin, Steven D. Koeber, Ernest Bowman-Cisneros, G. Wesley Patterson, Mark Robinson, Paul G. Lucey, Amanda R. Hendrix, Dana Hurley, Angela M. Stickle, Wayne Pryor

Earth and Space Exploration, School of (SESE)

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

12 Scopus citations

Abstract

The upper 25-100 nm of the lunar regolith within the permanently shaded regions (PSRs) of the Moon has been demonstrated to have significantly higher surface porosity than the average lunar regolith by observations that the Lyman-α albedo measured by the Lunar Reconnaissance Orbiter (LRO) Lyman Alpha Mapping Project (LAMP) is lower in the PSRs than the surrounding region. We find that two areas within the lunar south polar PSRs have significantly brighter Lyman-α albedos and correlate with the ejecta blankets of two small craters (<2 km diameter). This higher albedo is likely due to the ejecta blankets having significantly lower surface porosity than the surrounding PSRs. Furthermore, the ejecta blankets have much higher Circular Polarization Ratios (CPR), as measured by LRO Mini-RF, indicating increased surface roughness compared to the surrounding terrain. These combined observations suggest the detection of two craters that are very young on geologic timescales. From these observations we derive age limits for the two craters of 7-420 million years (Myr) based on dust transport processes and the radar brightness of the disconnected halos of the ejecta blankets.

Original language	English (US)
Pages (from-to)	114-120
Number of pages	7
Journal	Icarus
Volume	273
DOIs	https://doi.org/10.1016/j.icarus.2015.07.031
State	Published - Jul 15 2016

Keywords

Cratering
Impact processes
Moon, surface
Regoliths
Ultraviolet observations

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

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Mandt, K. E., Greathouse, T. K., Retherford, K. D., Randall Gladstone, G., Jordan, A. P., Lemelin, M., Koeber, S. D., Bowman-Cisneros, E., Wesley Patterson, G., Robinson, M., Lucey, P. G., Hendrix, A. R., Hurley, D., Stickle, A. M., & Pryor, W. (2016). LRO-LAMP detection of geologically young craters within lunar permanently shaded regions. Icarus, 273, 114-120. https://doi.org/10.1016/j.icarus.2015.07.031

Mandt, KE, Greathouse, TK, Retherford, KD, Randall Gladstone, G, Jordan, AP, Lemelin, M, Koeber, SD, Bowman-Cisneros, E, Wesley Patterson, G, Robinson, M, Lucey, PG, Hendrix, AR, Hurley, D, Stickle, AM & Pryor, W 2016, 'LRO-LAMP detection of geologically young craters within lunar permanently shaded regions', Icarus, vol. 273, pp. 114-120. https://doi.org/10.1016/j.icarus.2015.07.031

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title = "LRO-LAMP detection of geologically young craters within lunar permanently shaded regions",

abstract = "The upper 25-100 nm of the lunar regolith within the permanently shaded regions (PSRs) of the Moon has been demonstrated to have significantly higher surface porosity than the average lunar regolith by observations that the Lyman-α albedo measured by the Lunar Reconnaissance Orbiter (LRO) Lyman Alpha Mapping Project (LAMP) is lower in the PSRs than the surrounding region. We find that two areas within the lunar south polar PSRs have significantly brighter Lyman-α albedos and correlate with the ejecta blankets of two small craters (<2 km diameter). This higher albedo is likely due to the ejecta blankets having significantly lower surface porosity than the surrounding PSRs. Furthermore, the ejecta blankets have much higher Circular Polarization Ratios (CPR), as measured by LRO Mini-RF, indicating increased surface roughness compared to the surrounding terrain. These combined observations suggest the detection of two craters that are very young on geologic timescales. From these observations we derive age limits for the two craters of 7-420 million years (Myr) based on dust transport processes and the radar brightness of the disconnected halos of the ejecta blankets.",

keywords = "Cratering, Impact processes, Moon, surface, Regoliths, Ultraviolet observations",

author = "Mandt, {Kathleen E.} and Greathouse, {Thomas K.} and Retherford, {Kurt D.} and {Randall Gladstone}, G. and Jordan, {Andrew P.} and Myriam Lemelin and Koeber, {Steven D.} and Ernest Bowman-Cisneros and {Wesley Patterson}, G. and Mark Robinson and Lucey, {Paul G.} and Hendrix, {Amanda R.} and Dana Hurley and Stickle, {Angela M.} and Wayne Pryor",

note = "Publisher Copyright: {\textcopyright} 2015 Elsevier Inc.",

year = "2016",

month = jul,

day = "15",

doi = "10.1016/j.icarus.2015.07.031",

language = "English (US)",

volume = "273",

pages = "114--120",

journal = "Icarus",

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T1 - LRO-LAMP detection of geologically young craters within lunar permanently shaded regions

AU - Mandt, Kathleen E.

AU - Greathouse, Thomas K.

AU - Retherford, Kurt D.

AU - Randall Gladstone, G.

AU - Jordan, Andrew P.

AU - Lemelin, Myriam

AU - Koeber, Steven D.

AU - Bowman-Cisneros, Ernest

AU - Wesley Patterson, G.

AU - Robinson, Mark

AU - Lucey, Paul G.

AU - Hendrix, Amanda R.

AU - Hurley, Dana

AU - Stickle, Angela M.

AU - Pryor, Wayne

PY - 2016/7/15

Y1 - 2016/7/15

N2 - The upper 25-100 nm of the lunar regolith within the permanently shaded regions (PSRs) of the Moon has been demonstrated to have significantly higher surface porosity than the average lunar regolith by observations that the Lyman-α albedo measured by the Lunar Reconnaissance Orbiter (LRO) Lyman Alpha Mapping Project (LAMP) is lower in the PSRs than the surrounding region. We find that two areas within the lunar south polar PSRs have significantly brighter Lyman-α albedos and correlate with the ejecta blankets of two small craters (<2 km diameter). This higher albedo is likely due to the ejecta blankets having significantly lower surface porosity than the surrounding PSRs. Furthermore, the ejecta blankets have much higher Circular Polarization Ratios (CPR), as measured by LRO Mini-RF, indicating increased surface roughness compared to the surrounding terrain. These combined observations suggest the detection of two craters that are very young on geologic timescales. From these observations we derive age limits for the two craters of 7-420 million years (Myr) based on dust transport processes and the radar brightness of the disconnected halos of the ejecta blankets.

AB - The upper 25-100 nm of the lunar regolith within the permanently shaded regions (PSRs) of the Moon has been demonstrated to have significantly higher surface porosity than the average lunar regolith by observations that the Lyman-α albedo measured by the Lunar Reconnaissance Orbiter (LRO) Lyman Alpha Mapping Project (LAMP) is lower in the PSRs than the surrounding region. We find that two areas within the lunar south polar PSRs have significantly brighter Lyman-α albedos and correlate with the ejecta blankets of two small craters (<2 km diameter). This higher albedo is likely due to the ejecta blankets having significantly lower surface porosity than the surrounding PSRs. Furthermore, the ejecta blankets have much higher Circular Polarization Ratios (CPR), as measured by LRO Mini-RF, indicating increased surface roughness compared to the surrounding terrain. These combined observations suggest the detection of two craters that are very young on geologic timescales. From these observations we derive age limits for the two craters of 7-420 million years (Myr) based on dust transport processes and the radar brightness of the disconnected halos of the ejecta blankets.

KW - Cratering

KW - Impact processes

KW - Moon, surface

KW - Regoliths

KW - Ultraviolet observations

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SN - 0019-1035

VL - 273

SP - 114

EP - 120

JO - Icarus

JF - Icarus

ER -

LRO-LAMP detection of geologically young craters within lunar permanently shaded regions

Abstract

Keywords

ASJC Scopus subject areas

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