Human-assisted Sample Return Mission at the Schrödinger Basin, Lunar Far Side, Using a New Geologic Map and Rover Traverses

The Schrödinger basin on the south polar lunar far side has been highlighted as a promising target for future exploration. This report provides a high-resolution geologic map in the southwest peak-ring (SWPR) area of the Schrödinger basin, emphasizing structural features and detailed mapping of expo...

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Published in:The Planetary Science Journal
Main Authors: Czaplinski, E. C., Harrington, E. M., Bell, S. K., Tolometti, G. D., Farrant, B. E., Bickel, V. T., Honniball, C. I., Martinez, S. N., Rogaski, A., Sargeant, Hannah, Kring, D. A.
Format: Article in Journal/Newspaper
Language:unknown
Published: The American Astronomical Society 2021
Subjects:
South Pole
Southwest Peak
South pole
Online Access:https://oro.open.ac.uk/75681/
https://oro.open.ac.uk/75681/1/pdf.pdf
https://doi.org/10.3847/psj/abdb34
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author Czaplinski, E. C.
Harrington, E. M.
Bell, S. K.
Tolometti, G. D.
Farrant, B. E.
Bickel, V. T.
Honniball, C. I.
Martinez, S. N.
Rogaski, A.
Sargeant, Hannah
Kring, D. A.
author_facet Czaplinski, E. C.
Harrington, E. M.
Bell, S. K.
Tolometti, G. D.
Farrant, B. E.
Bickel, V. T.
Honniball, C. I.
Martinez, S. N.
Rogaski, A.
Sargeant, Hannah
Kring, D. A.
author_sort Czaplinski, E. C.
collection The Open University: Open Research Online (ORO)
container_issue 2
container_start_page 51
container_title The Planetary Science Journal
container_volume 2
description The Schrödinger basin on the south polar lunar far side has been highlighted as a promising target for future exploration. This report provides a high-resolution geologic map in the southwest peak-ring (SWPR) area of the Schrödinger basin, emphasizing structural features and detailed mapping of exposed outcrops within the peak ring. Outcrops are correlated with mineralogical data from the Moon Mineralogical Mapper instrument. Geologic mapping reveals a complex structural history within the basin through a system of radially oriented faults. Further, the geologic map shows both faulted and magmatic contacts between peak-ring mineralogies, providing both structural and magmatic context for understanding lunar crustal evolution and polar region processes. To investigate these relationships and address key scientific concepts and goals from the National Research Council (NRC) report, we propose three traverse paths for a robotic sample return mission in the SWPR area. These traverses focus on addressing the highest priority science concepts and goals by investigating known outcrops with diverse mineralogical associations and visible contacts among them. Coinciding with the preparation for the 2024 Artemis III mission, NASA is increasing the priority of robotic exploration at the lunar south pole before the next crewed mission to the Moon. Through mapping the Schrödinger SWPR, we identified the extent of different lunar crustal mineralogies, inferred their geologic relationships and distribution, and pinpointed traversable routes to sample spectrally diverse outcrops and outcrop-derived boulders. The SWPR region is therefore a promising potential target for future exploration, capable of addressing multiple high-priority lunar science goals.
format Article in Journal/Newspaper
genre South pole
genre_facet South pole
geographic South Pole
Southwest Peak
geographic_facet South Pole
Southwest Peak
id ftopenunivgb:oai:oro.open.ac.uk:75681
institution Open Polar
language unknown
long_lat ENVELOPE(173.212,173.212,52.913,52.913)
op_collection_id ftopenunivgb
op_doi https://doi.org/10.3847/psj/abdb34
op_relation https://oro.open.ac.uk/75681/1/pdf.pdf
Czaplinski, E. C.; Harrington, E. M.; Bell, S. K.; Tolometti, G. D.; Farrant, B. E.; Bickel, V. T.; Honniball, C. I.; Martinez, S. N.; Rogaski, A.; Sargeant, Hannah <http://oro.open.ac.uk/view/person/hs7243.html> and Kring, D. A. (2021). Human-assisted Sample Return Mission at the Schrödinger Basin, Lunar Far Side, Using a New Geologic Map and Rover Traverses. The Planetary Science Journal, 2(2), article no. 51.
publishDate 2021
publisher The American Astronomical Society
record_format openpolar
spelling ftopenunivgb:oai:oro.open.ac.uk:75681 2025-01-17T00:52:39+00:00 Human-assisted Sample Return Mission at the Schrödinger Basin, Lunar Far Side, Using a New Geologic Map and Rover Traverses Czaplinski, E. C. Harrington, E. M. Bell, S. K. Tolometti, G. D. Farrant, B. E. Bickel, V. T. Honniball, C. I. Martinez, S. N. Rogaski, A. Sargeant, Hannah Kring, D. A. 2021-04 application/pdf https://oro.open.ac.uk/75681/ https://oro.open.ac.uk/75681/1/pdf.pdf https://doi.org/10.3847/psj/abdb34 unknown The American Astronomical Society https://oro.open.ac.uk/75681/1/pdf.pdf Czaplinski, E. C.; Harrington, E. M.; Bell, S. K.; Tolometti, G. D.; Farrant, B. E.; Bickel, V. T.; Honniball, C. I.; Martinez, S. N.; Rogaski, A.; Sargeant, Hannah <http://oro.open.ac.uk/view/person/hs7243.html> and Kring, D. A. (2021). Human-assisted Sample Return Mission at the Schrödinger Basin, Lunar Far Side, Using a New Geologic Map and Rover Traverses. The Planetary Science Journal, 2(2), article no. 51. Journal Item Public PeerReviewed 2021 ftopenunivgb https://doi.org/10.3847/psj/abdb34 2023-05-28T06:05:12Z The Schrödinger basin on the south polar lunar far side has been highlighted as a promising target for future exploration. This report provides a high-resolution geologic map in the southwest peak-ring (SWPR) area of the Schrödinger basin, emphasizing structural features and detailed mapping of exposed outcrops within the peak ring. Outcrops are correlated with mineralogical data from the Moon Mineralogical Mapper instrument. Geologic mapping reveals a complex structural history within the basin through a system of radially oriented faults. Further, the geologic map shows both faulted and magmatic contacts between peak-ring mineralogies, providing both structural and magmatic context for understanding lunar crustal evolution and polar region processes. To investigate these relationships and address key scientific concepts and goals from the National Research Council (NRC) report, we propose three traverse paths for a robotic sample return mission in the SWPR area. These traverses focus on addressing the highest priority science concepts and goals by investigating known outcrops with diverse mineralogical associations and visible contacts among them. Coinciding with the preparation for the 2024 Artemis III mission, NASA is increasing the priority of robotic exploration at the lunar south pole before the next crewed mission to the Moon. Through mapping the Schrödinger SWPR, we identified the extent of different lunar crustal mineralogies, inferred their geologic relationships and distribution, and pinpointed traversable routes to sample spectrally diverse outcrops and outcrop-derived boulders. The SWPR region is therefore a promising potential target for future exploration, capable of addressing multiple high-priority lunar science goals. Article in Journal/Newspaper South pole The Open University: Open Research Online (ORO) South Pole Southwest Peak ENVELOPE(173.212,173.212,52.913,52.913) The Planetary Science Journal 2 2 51
spellingShingle Czaplinski, E. C.
Harrington, E. M.
Bell, S. K.
Tolometti, G. D.
Farrant, B. E.
Bickel, V. T.
Honniball, C. I.
Martinez, S. N.
Rogaski, A.
Sargeant, Hannah
Kring, D. A.
Human-assisted Sample Return Mission at the Schrödinger Basin, Lunar Far Side, Using a New Geologic Map and Rover Traverses
title Human-assisted Sample Return Mission at the Schrödinger Basin, Lunar Far Side, Using a New Geologic Map and Rover Traverses
title_full Human-assisted Sample Return Mission at the Schrödinger Basin, Lunar Far Side, Using a New Geologic Map and Rover Traverses
title_fullStr Human-assisted Sample Return Mission at the Schrödinger Basin, Lunar Far Side, Using a New Geologic Map and Rover Traverses
title_full_unstemmed Human-assisted Sample Return Mission at the Schrödinger Basin, Lunar Far Side, Using a New Geologic Map and Rover Traverses
title_short Human-assisted Sample Return Mission at the Schrödinger Basin, Lunar Far Side, Using a New Geologic Map and Rover Traverses
title_sort human-assisted sample return mission at the schrödinger basin, lunar far side, using a new geologic map and rover traverses
url https://oro.open.ac.uk/75681/
https://oro.open.ac.uk/75681/1/pdf.pdf
https://doi.org/10.3847/psj/abdb34

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