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Experimental Investigation of the Atmosphere-Regolith Water Cycle on Present-Day Mars

The water content of the upper layers of the surface of Mars is not yet quantified. Laboratory simulations are the only feasible way to investigate this in a controlled way on Earth, and then compare it with remote and in situ observations of spacecrafts on Mars. Describing the processes that may in...

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Autores principales: Vakkada Ramachandran, Abhilash, Zorzano, María-Paz, Martín-Torres, Javier
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2021
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8588207/
https://www.ncbi.nlm.nih.gov/pubmed/34770727
http://dx.doi.org/10.3390/s21217421
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author Vakkada Ramachandran, Abhilash
Zorzano, María-Paz
Martín-Torres, Javier
author_facet Vakkada Ramachandran, Abhilash
Zorzano, María-Paz
Martín-Torres, Javier
author_sort Vakkada Ramachandran, Abhilash
collection PubMed
description The water content of the upper layers of the surface of Mars is not yet quantified. Laboratory simulations are the only feasible way to investigate this in a controlled way on Earth, and then compare it with remote and in situ observations of spacecrafts on Mars. Describing the processes that may induce changes in the water content of the surface is critical to determine the present-day habitability of the Martian surface, to understand the atmospheric water cycle, and to estimate the efficiency of future water extraction procedures from the regolith for In Situ Resource Utilization (ISRU). This paper illustrates the application of the SpaceQ facility to simulate the near-surface water cycle under Martian conditions. Rover Environmental Monitoring Station (REMS) observations at Gale crater show a non-equilibrium situation in the atmospheric H(2)O volume mixing ratio (VMR) at night-time, and there is a decrease in the atmospheric water content by up to 15 g/m(2) within a few hours. This reduction suggests that the ground may act at night as a cold sink scavenging atmospheric water. Here, we use an experimental approach to investigate the thermodynamic and kinetics of water exchange between the atmosphere, a non-porous surface (LN(2)-chilled metal), various salts, Martian regolith simulant, and mixtures of salts and simulant within an environment which is close to saturation. We have conducted three experiments: the stability of pure liquid water around the vicinity of the triple point is studied in experiment 1, as well as observing the interchange of water between the atmosphere and the salts when the surface is saturated; in experiment 2, the salts were mixed with Mojave Martian Simulant (MMS) to observe changes in the texture of the regolith caused by the interaction with hydrates and liquid brines, and to quantify the potential of the Martian regolith to absorb and retain water; and experiment 3 investigates the evaporation of pure liquid water away from the triple point temperature when both the air and ground are at the same temperature and the relative humidity is near saturation. We show experimentally that frost can form spontaneously on a surface when saturation is reached and that, when the temperature is above 273.15 K (0 °C), this frost can transform into liquid water, which can persist for up to 3.5 to 4.5 h at Martian surface conditions. For comparison, we study the behavior of certain deliquescent salts that exist on the Martian surface, which can increase their mass between 32% and 85% by absorption of atmospheric water within a few hours. A mixture of these salts in a 10% concentration with simulant produces an aggregated granular structure with a water gain of approximately 18- to 50-wt%. Up to 53% of the atmospheric water was captured by the simulated ground, as pure liquid water, hydrate, or brine.
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spelling pubmed-85882072021-11-13 Experimental Investigation of the Atmosphere-Regolith Water Cycle on Present-Day Mars Vakkada Ramachandran, Abhilash Zorzano, María-Paz Martín-Torres, Javier Sensors (Basel) Article The water content of the upper layers of the surface of Mars is not yet quantified. Laboratory simulations are the only feasible way to investigate this in a controlled way on Earth, and then compare it with remote and in situ observations of spacecrafts on Mars. Describing the processes that may induce changes in the water content of the surface is critical to determine the present-day habitability of the Martian surface, to understand the atmospheric water cycle, and to estimate the efficiency of future water extraction procedures from the regolith for In Situ Resource Utilization (ISRU). This paper illustrates the application of the SpaceQ facility to simulate the near-surface water cycle under Martian conditions. Rover Environmental Monitoring Station (REMS) observations at Gale crater show a non-equilibrium situation in the atmospheric H(2)O volume mixing ratio (VMR) at night-time, and there is a decrease in the atmospheric water content by up to 15 g/m(2) within a few hours. This reduction suggests that the ground may act at night as a cold sink scavenging atmospheric water. Here, we use an experimental approach to investigate the thermodynamic and kinetics of water exchange between the atmosphere, a non-porous surface (LN(2)-chilled metal), various salts, Martian regolith simulant, and mixtures of salts and simulant within an environment which is close to saturation. We have conducted three experiments: the stability of pure liquid water around the vicinity of the triple point is studied in experiment 1, as well as observing the interchange of water between the atmosphere and the salts when the surface is saturated; in experiment 2, the salts were mixed with Mojave Martian Simulant (MMS) to observe changes in the texture of the regolith caused by the interaction with hydrates and liquid brines, and to quantify the potential of the Martian regolith to absorb and retain water; and experiment 3 investigates the evaporation of pure liquid water away from the triple point temperature when both the air and ground are at the same temperature and the relative humidity is near saturation. We show experimentally that frost can form spontaneously on a surface when saturation is reached and that, when the temperature is above 273.15 K (0 °C), this frost can transform into liquid water, which can persist for up to 3.5 to 4.5 h at Martian surface conditions. For comparison, we study the behavior of certain deliquescent salts that exist on the Martian surface, which can increase their mass between 32% and 85% by absorption of atmospheric water within a few hours. A mixture of these salts in a 10% concentration with simulant produces an aggregated granular structure with a water gain of approximately 18- to 50-wt%. Up to 53% of the atmospheric water was captured by the simulated ground, as pure liquid water, hydrate, or brine. MDPI 2021-11-08 /pmc/articles/PMC8588207/ /pubmed/34770727 http://dx.doi.org/10.3390/s21217421 Text en © 2021 by the authors. https://creativecommons.org/licenses/by/4.0/Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Vakkada Ramachandran, Abhilash
Zorzano, María-Paz
Martín-Torres, Javier
Experimental Investigation of the Atmosphere-Regolith Water Cycle on Present-Day Mars
title Experimental Investigation of the Atmosphere-Regolith Water Cycle on Present-Day Mars
title_full Experimental Investigation of the Atmosphere-Regolith Water Cycle on Present-Day Mars
title_fullStr Experimental Investigation of the Atmosphere-Regolith Water Cycle on Present-Day Mars
title_full_unstemmed Experimental Investigation of the Atmosphere-Regolith Water Cycle on Present-Day Mars
title_short Experimental Investigation of the Atmosphere-Regolith Water Cycle on Present-Day Mars
title_sort experimental investigation of the atmosphere-regolith water cycle on present-day mars
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8588207/
https://www.ncbi.nlm.nih.gov/pubmed/34770727
http://dx.doi.org/10.3390/s21217421
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