Simulating Ejecta Blown off the Lunar Surface due to Landing Spacecraft using the Mercury N-body Integrator

The experiences of the Apollo lunar landings revealed the danger lunar dust can pose to surrounding hardware, outposts, and orbiting spacecraft. Future lunar missions such as the Artemis program will require more information about the trajectories of ejecta blown by landers to protect orbiting space...

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Bibliographic Details
Main Author: Rivera, Isabel
Format: Text
Language:English
Published: STARS 2021
Subjects:
Space Vehicles
The Sun and the Solar System
North Pole
South Pole
South pole
Online Access:https://stars.library.ucf.edu/etd2020/749
https://stars.library.ucf.edu/context/etd2020/article/1748/viewcontent/uc.pdf
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record_format openpolar
spelling ftunicentralflor:oai:stars.library.ucf.edu:etd2020-1748 2023-06-11T04:15:10+02:00 Simulating Ejecta Blown off the Lunar Surface due to Landing Spacecraft using the Mercury N-body Integrator Rivera, Isabel 2021-01-01T08:00:00Z application/pdf https://stars.library.ucf.edu/etd2020/749 https://stars.library.ucf.edu/context/etd2020/article/1748/viewcontent/uc.pdf English eng STARS https://stars.library.ucf.edu/etd2020/749 https://stars.library.ucf.edu/context/etd2020/article/1748/viewcontent/uc.pdf Electronic Theses and Dissertations, 2020- Space Vehicles The Sun and the Solar System text 2021 ftunicentralflor 2023-05-01T18:01:15Z The experiences of the Apollo lunar landings revealed the danger lunar dust can pose to surrounding hardware, outposts, and orbiting spacecraft. Future lunar missions such as the Artemis program will require more information about the trajectories of ejecta blown by landers to protect orbiting spacecraft such as the Lunar Gateway. In this paper, we simulate lunar lander ejecta trajectories using the Mercury N-body integrator. We placed cones of test particles on the Moon at the North Pole, South Pole, and Equator with various ejection speeds and angles. The results show that particles ejected at speeds near the Moon's escape velocity can take from several days to weeks to re-impact the lunar surface. The time particles spend in the vicinity of the Moon varies mostly by location. Particles stay aloft after 30 days at launch speeds as low as 2.142 km/s when launched from the Equator. Number density maps and flux density maps of the particle trajectories reveal that particles launched from the South Pole are likely to impact the Lunar Gateway at its orbit near periselene at ejection speeds as low as 2.142 km/s. Particles launched from the Equator also reach the altitude of the Gateway orbit. Particles ejected from the North Pole can impact the Gateway along its orbit at ejections speeds somewhere between 2.3324 and 2.3562 km/s. Text North Pole South pole University of Central Florida (UCF): STARS (Showcase of Text, Archives, Research & Scholarship) North Pole South Pole
institution Open Polar
collection University of Central Florida (UCF): STARS (Showcase of Text, Archives, Research & Scholarship)
op_collection_id ftunicentralflor
language English
topic Space Vehicles
The Sun and the Solar System
spellingShingle Space Vehicles
The Sun and the Solar System
Rivera, Isabel
Simulating Ejecta Blown off the Lunar Surface due to Landing Spacecraft using the Mercury N-body Integrator
topic_facet Space Vehicles
The Sun and the Solar System
description The experiences of the Apollo lunar landings revealed the danger lunar dust can pose to surrounding hardware, outposts, and orbiting spacecraft. Future lunar missions such as the Artemis program will require more information about the trajectories of ejecta blown by landers to protect orbiting spacecraft such as the Lunar Gateway. In this paper, we simulate lunar lander ejecta trajectories using the Mercury N-body integrator. We placed cones of test particles on the Moon at the North Pole, South Pole, and Equator with various ejection speeds and angles. The results show that particles ejected at speeds near the Moon's escape velocity can take from several days to weeks to re-impact the lunar surface. The time particles spend in the vicinity of the Moon varies mostly by location. Particles stay aloft after 30 days at launch speeds as low as 2.142 km/s when launched from the Equator. Number density maps and flux density maps of the particle trajectories reveal that particles launched from the South Pole are likely to impact the Lunar Gateway at its orbit near periselene at ejection speeds as low as 2.142 km/s. Particles launched from the Equator also reach the altitude of the Gateway orbit. Particles ejected from the North Pole can impact the Gateway along its orbit at ejections speeds somewhere between 2.3324 and 2.3562 km/s.
format Text
author Rivera, Isabel
author_facet Rivera, Isabel
author_sort Rivera, Isabel
title Simulating Ejecta Blown off the Lunar Surface due to Landing Spacecraft using the Mercury N-body Integrator
title_short Simulating Ejecta Blown off the Lunar Surface due to Landing Spacecraft using the Mercury N-body Integrator
title_full Simulating Ejecta Blown off the Lunar Surface due to Landing Spacecraft using the Mercury N-body Integrator
title_fullStr Simulating Ejecta Blown off the Lunar Surface due to Landing Spacecraft using the Mercury N-body Integrator
title_full_unstemmed Simulating Ejecta Blown off the Lunar Surface due to Landing Spacecraft using the Mercury N-body Integrator
title_sort simulating ejecta blown off the lunar surface due to landing spacecraft using the mercury n-body integrator
publisher STARS
publishDate 2021
url https://stars.library.ucf.edu/etd2020/749
https://stars.library.ucf.edu/context/etd2020/article/1748/viewcontent/uc.pdf
geographic North Pole
South Pole
geographic_facet North Pole
South Pole
genre North Pole
South pole
genre_facet North Pole
South pole
op_source Electronic Theses and Dissertations, 2020-
op_relation https://stars.library.ucf.edu/etd2020/749
https://stars.library.ucf.edu/context/etd2020/article/1748/viewcontent/uc.pdf
_version_ 1768371791008366592

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