A lower limit of atmospheric pressure on early Mars inferred from nitrogen and argon isotopic compositions

Kurokawa, Hiroyuki; Kurosawa, Kosuke; Usui, Tomohiro

doi:10.1016/j.icarus.2017.08.020

Cited by 57 publications

(79 citation statements)

References 117 publications

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“…The baseline ocean of Di Achille and Hynek (2010) (light blue shaded region) was assumed in these calculations. Craddock & Lorenz, 2017;Hu et al, 2015;Kite et al, 2014;Kurokawa et al, 2018) (Figure 5a). These numbers also corroborate recent results from 1-D RC climate modeling (Ramirez, 2017;Wordsworth et al, 2017).…”

Section: Warm Vs Cold Start Studymentioning

confidence: 99%

Climate Simulations of Early Mars With Estimated Precipitation, Runoff, and Erosion Rates

2020

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The debate over the early Martian climate is among the most intriguing in planetary science. Although the geologic evidence generally supports a warmer and wetter climate, climate models have had difficulty simulating such a scenario, leading some to suggest that the observed fluvial geology (e.g., valley networks, modified landscapes) on the Martian surface could have formed in a cold climate instead. However, as we have originally predicted using a single‐column radiative‐convective climate model (Ramirez, Kopparapu, Zugger, et al., 2014, https://doi.org/10.1038/ngeo2000), warming from CO2‐H2 collision‐induced absorption on a volcanically active early Mars could have raised mean surface temperatures above the freezing point, with later calculations showing that this is achievable with hydrogen concentrations as low as ~1%. Nevertheless, these predictions should be tested against more complex models. Here we use an advanced energy balance model that includes a northern lowlands ocean to show that mean surface temperatures near or slightly above the freezing point of water were necessary to carve the valley networks. Our scenario is consistent with a relatively large ocean as has been suggested. Valley network distributions would have been global prior to subsequent removal processes. At lower mean surface temperatures and smaller ocean sizes, precipitation and surface erosion efficiency diminish. The warm period may have been approximately <107 years, perhaps suggesting that episodic warming mechanisms were not needed. Atmospheric collapse and permanently glaciated conditions occur once surface ice coverage exceeds a threshold depending on collision‐induced absorption assumptions. Our results support an early warm and semiarid climate consistent with many geologic observations.

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Section: Warm Vs Cold Start Studymentioning

confidence: 99%

Climate Simulations of Early Mars With Estimated Precipitation, Runoff, and Erosion Rates

2020

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“…Laboratory experiments do not allow for studying the long accumulation of doses of relatively low intensity in the microbial biomass of natural soil. The main question of the present study is how long the biosphere of Mars could be maintained after the supposed catastrophic change in planetary conditions [24][25][26][27][28][29], the gradual loss of the atmosphere [30], and the formation of a modern climate.…”

Section: Introductionmentioning

confidence: 97%

Survivability of Soil and Permafrost Microbial Communities after Irradiation with Accelerated Electrons under Simulated Martian and Open Space Conditions

et al. 2018

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Abstract:One of the prior current astrobiological tasks is revealing the limits of microbial resistance to extraterrestrial conditions. Much attention is paid to ionizing radiation, since it can prevent the preservation and spread of life outside the Earth. The aim of this research was to study the impact of accelerated electrons (~1 MeV) as component of space radiation on microbial communities in their natural habitat-the arid soil and ancient permafrost, and also on the pure bacterial cultures that were isolated from these ecotopes. The irradiation was carried out at low pressure (~0.01 Torr) and low temperature (−130 • C) to simulate the conditions of Mars or outer space. High doses of 10 kGy and 100 kGy were used to assess the effect of dose accumulation in inactive and hypometabolic cells, depending on environmental conditions under long-term irradiation estimated on a geological time scale. It was shown that irradiation with accelerated electrons in the applied doses did not sterilize native samples from Earth extreme habitats. The data obtained suggests that viable Earth-like microorganisms can be preserved in the anabiotic state for at least 1.3 and 20 million years in the regolith of modern Mars in the shallow subsurface layer and at a 5 m depth, respectively. In addition, the results of the study indicate the possibility of maintaining terrestrial like life in the ice of Europa at a 10 cm depth for at least~170 years or for at least 400 thousand years in open space within meteorites. It is established that bacteria in natural habitat has a much higher resistance to in situ irradiation with accelerated electrons when compared to their stability in pure isolated cultures. Thanks to the protective properties of the heterophase environment and the interaction between microbial populations even radiosensitive microorganisms as members of the native microbial communities are able to withstand very high doses of ionizing radiation.

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“…Meteorite noble gas data have been interpreted to require P > 0.5 bar at ~4.1 Ga, but also P < 0.4 bar at ~4.1 Ga (Cassata et al 2012, Kurokawa et al 2018). (Manga et al 2012; single data point); (6) modern atmosphere; (7) modern atmosphere + buried CO2 ice; (8*) meteorite trapped-atmosphere isotopic ratios (Kurokawa et al 2018); (9 -range spanned by brown dashed lines) modern escape-to-space measured by Mars Atmosphere and Volatile Evolution Mission (MAVEN) and Mars Express (MEX) spacecraft, extrapolated into past (Barabash et al 2017, Lillis et al 2017, Brain et al 2017, Ramstad et al 2018); (10*) bedform wavelengths (Lapôtre et al 2016). Approximate and model-dependent implications for climate are shown by background colours.…”

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Geologic Constraints on Early Mars Climate

Kite

2019

Space Sci Rev

108

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Early Mars climate research has well-defined goals (Mars Exploration Program Analysis Group 2018). Achieving these goals requires geologists and climate modelers to coordinate. Coordination is easier if results are expressed in terms of well-defined parameters. Key parameters include the following quantitative geologic constraints.(1) Cumulative post-3.4 Ga precipitation-sourced water runoff in some places exceeded 1 km column. (2) There is no single Early Mars climate problem: the traces of ≥2 riverforming periods are seen. Relative to rivers that formed earlier in Mars history, rivers that formed later in Mars history are found preferentially at lower elevations, and show a stronger dependence on latitude. (3) The duration of the longest individual river-forming climate was >(10 2 -10 3 ) yr, based on paleolake hydrology. (4) Peak runoff production was >0.1 mm/hr. However, (5) peak runoff production was intermittent, sustained (in a given catchment) for only <10% of the duration of river-forming climates. (6) The cumulative number of wet years during the valley-network-forming period was >10 5 yr. (7) Post-Noachian light-toned, layered sedimentary rocks took >10 7 yr to accumulate. However, (8) an "average" place on Mars saw water for <10 7 yr after the Noachian, suggesting that the river-forming climates were interspersed with long globally-dry intervals. (9) Geologic proxies for Early Mars atmospheric pressure indicate pressure was not less than 0.012 bar but not much more than 1 bar. A truth table of these geologic constraints versus currently published climate models shows that the late persistence of river-forming climates, combined with the long duration of individual lake-forming climates, is a challenge for most models. Kraal, Erin R.; Asphaug, Erik; Moore, Jeffery M.; Howard, Alan; Bredt, Adam, 2008a, Catalogue of large alluvial fans in martian impact craters, Icarus, 194, 1, 101-110. Kraal, Erin R.; van Dijk, Maurits; Postma, George; Kleinhans, Maarten G., 2008b, Martian stepped-delta formation by rapid water release, Nature, 451, 7181, 973-976.Kurahashi-Nakamura, Takasumi; Tajika, Eiichi, 2006, Atmospheric collapse and transport of carbon dioxide into the subsurface on early Mars, Geophys. Res. Lett., 33, L18205.

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A lower limit of atmospheric pressure on early Mars inferred from nitrogen and argon isotopic compositions

Cited by 57 publications

References 117 publications

Climate Simulations of Early Mars With Estimated Precipitation, Runoff, and Erosion Rates

Climate Simulations of Early Mars With Estimated Precipitation, Runoff, and Erosion Rates

Survivability of Soil and Permafrost Microbial Communities after Irradiation with Accelerated Electrons under Simulated Martian and Open Space Conditions

Geologic Constraints on Early Mars Climate

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