Plume-Surface Interactions due to Spacecraft Landings and The Discovery of Water on Mars.
Pulsed supersonic jets or rocket plumes have different surface flow physics than steady jets, in particular in tenuous atmospheres such as that of Mars where jets are collimated over large distances compared to their diameters. We show that plate shock formation and collapse during each cycle of pul...
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| Online Access: | https://hdl.handle.net/2027.42/78975 |
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ftumdeepblue:oai:deepblue.lib.umich.edu:2027.42/78975 2024-01-07T09:41:29+01:00 Plume-Surface Interactions due to Spacecraft Landings and The Discovery of Water on Mars. Mehta, Manish Renno, Nilton O. Bougher, Stephen Gallimore, Alec D. Sengupta, Anita 40095576 bytes 1373 bytes application/pdf text/plain https://hdl.handle.net/2027.42/78975 en_US eng https://hdl.handle.net/2027.42/78975 Supersonic Jets/Rocket Plumes/Gas Dynamics Cratering Physics Multiphase Fluid Dynamics Radiometry Mars Water Spacecraft Entry Descent and Landing Aerospace Engineering Atmospheric Oceanic and Space Sciences Physics Engineering Science Thesis ftumdeepblue 2023-12-10T17:49:12Z Pulsed supersonic jets or rocket plumes have different surface flow physics than steady jets, in particular in tenuous atmospheres such as that of Mars where jets are collimated over large distances compared to their diameters. We show that plate shock formation and collapse during each cycle of pulsed jets impinging on a surface causes large pressure fluctuations capable of producing extensive erosion during spacecraft landings. Here, we study the pressure loads and erosion caused by pulsed jets of the Phoenix spacecraft on the surface of Mars and its implications to engineering and science. While steady thruster jets caused only modest surface erosion during the landings of previous spacecraft on the moon and Mars, the pulsed jets from Phoenix led to extensive alteration of its landing site on the martian arctic, exposed a large fraction of the subsurface water ice under the lander, and led to the discovery of evidence for liquid saline water on Mars. We report the discovery of the ‘explosive erosion’ process that led to this extensive erosion and evidence for liquid water. We show that the impingement of supersonic pulsed jets fluidizes porous soils and forms cyclic shock waves that propagate through the soil producing erosion rates more than an order of magnitude larger than that of other jet-induced processes. The understanding of ‘explosive erosion’ allows the calculation of bulk physical properties of the soils altered by it, provides new insights into the behavior of granular flow at extreme conditions, and explains the alteration of the Phoenix landing site at the northern arctic plains of Mars. We then show new photometric evidence that the Phoenix spacecraft imaged liquid saline water in the arctic, and that deliquescence causes liquid water to sporadically flow in the polar region. This finding also corroborates the hypothesis that the thermodynamics of freezing/thaw cycles leads to the seasonal formation of liquid saline water where ice and salts exist near the surface. Finally, we show broadband ... Thesis Arctic University of Michigan: Deep Blue Arctic |
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English |
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Supersonic Jets/Rocket Plumes/Gas Dynamics Cratering Physics Multiphase Fluid Dynamics Radiometry Mars Water Spacecraft Entry Descent and Landing Aerospace Engineering Atmospheric Oceanic and Space Sciences Physics Engineering Science |
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Supersonic Jets/Rocket Plumes/Gas Dynamics Cratering Physics Multiphase Fluid Dynamics Radiometry Mars Water Spacecraft Entry Descent and Landing Aerospace Engineering Atmospheric Oceanic and Space Sciences Physics Engineering Science Mehta, Manish Plume-Surface Interactions due to Spacecraft Landings and The Discovery of Water on Mars. |
| topic_facet |
Supersonic Jets/Rocket Plumes/Gas Dynamics Cratering Physics Multiphase Fluid Dynamics Radiometry Mars Water Spacecraft Entry Descent and Landing Aerospace Engineering Atmospheric Oceanic and Space Sciences Physics Engineering Science |
| description |
Pulsed supersonic jets or rocket plumes have different surface flow physics than steady jets, in particular in tenuous atmospheres such as that of Mars where jets are collimated over large distances compared to their diameters. We show that plate shock formation and collapse during each cycle of pulsed jets impinging on a surface causes large pressure fluctuations capable of producing extensive erosion during spacecraft landings. Here, we study the pressure loads and erosion caused by pulsed jets of the Phoenix spacecraft on the surface of Mars and its implications to engineering and science. While steady thruster jets caused only modest surface erosion during the landings of previous spacecraft on the moon and Mars, the pulsed jets from Phoenix led to extensive alteration of its landing site on the martian arctic, exposed a large fraction of the subsurface water ice under the lander, and led to the discovery of evidence for liquid saline water on Mars. We report the discovery of the ‘explosive erosion’ process that led to this extensive erosion and evidence for liquid water. We show that the impingement of supersonic pulsed jets fluidizes porous soils and forms cyclic shock waves that propagate through the soil producing erosion rates more than an order of magnitude larger than that of other jet-induced processes. The understanding of ‘explosive erosion’ allows the calculation of bulk physical properties of the soils altered by it, provides new insights into the behavior of granular flow at extreme conditions, and explains the alteration of the Phoenix landing site at the northern arctic plains of Mars. We then show new photometric evidence that the Phoenix spacecraft imaged liquid saline water in the arctic, and that deliquescence causes liquid water to sporadically flow in the polar region. This finding also corroborates the hypothesis that the thermodynamics of freezing/thaw cycles leads to the seasonal formation of liquid saline water where ice and salts exist near the surface. Finally, we show broadband ... |
| author2 |
Renno, Nilton O. Bougher, Stephen Gallimore, Alec D. Sengupta, Anita |
| format |
Thesis |
| author |
Mehta, Manish |
| author_facet |
Mehta, Manish |
| author_sort |
Mehta, Manish |
| title |
Plume-Surface Interactions due to Spacecraft Landings and The Discovery of Water on Mars. |
| title_short |
Plume-Surface Interactions due to Spacecraft Landings and The Discovery of Water on Mars. |
| title_full |
Plume-Surface Interactions due to Spacecraft Landings and The Discovery of Water on Mars. |
| title_fullStr |
Plume-Surface Interactions due to Spacecraft Landings and The Discovery of Water on Mars. |
| title_full_unstemmed |
Plume-Surface Interactions due to Spacecraft Landings and The Discovery of Water on Mars. |
| title_sort |
plume-surface interactions due to spacecraft landings and the discovery of water on mars. |
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https://hdl.handle.net/2027.42/78975 |
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Arctic |
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Arctic |
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Arctic |
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Arctic |
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https://hdl.handle.net/2027.42/78975 |
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