Surface temperature of Martian regolith with polygonal features: influence of the subsurface water ice

Discriminating between abiotic and biotic signatures of amino acids and fatty acids on extraterrestrial ocean worlds is key to the search for life and its emergence on these bodies. Cryovolcanically active ocean worlds, such as Enceladus and potentially Europa, eject water ice grains formed from subsurface water into space. The ejected ice grains can be sampled by impact ionization mass spectrometers onboard spacecraft &#8211; such as Cassini&#8217;s Cosmic Dust Analyzer (CDA) &#8211; thereby exploring the habitability of the subsurface oceans. Complex organic macromolecules [1], as well as nitrogen- and oxygen-bearing organics that could act as amino acid precursors [2], were recently detected by the CDA in Enceladean ice grains. The next step is to determine whether potential biosignatures, such as amino acids and fatty acids, may also be detected using impact ionization mass spectrometry and whether abiotic and biotic signatures can be distinguished after a hypervelocity ice grain impact.Previous experiments with an analogue Laser Induced Liquid Beam Ion Desorption (LILBID) spectrometer, proven to accurately reproduce the mass spectra of water ice grains at different impact speeds in space [3], have shown that most amino acids, fatty acids and peptides in pure water ice grains can be detected at nanomolar concentrations [4]. Here, we investigate the mass spectral appearance and detection limits of amino acids and fatty acids, in proportions representative of either biotic or abiotic formation processes, in a more realistic, Enceladus-like scenario. The analytes are mixed with over twenty additional organic (e.g., carboxylic acids) and inorganic background components (e.g., salts) suitable for ice grains formed from Enceladean ocean water which has interacted with the moon&#8217;s rocky core.We find it is possible to distinguish and identify abiotic and biotic mass spectral fingerprints of potential biosignatures from the background even under these difficult conditions. In contrast to our previous work, we here find that amino acids and fatty acids form characteristic sodium-complexed molecular cations in a salty matrix. Detection limits of the organic biosignatures depend strongly on their Pka values and the salinity of the ice grains. Amino acid and fatty acid concentrations realistic for abiotic and biotic processes in the Enceladus ocean can be detected and characteristic abiotic and biotic mass spectral signatures can be clearly distinguished from each other [5]. We infer from our experiments that ice grain encounter velocities of 3 &#8211; 6 km/s are most appropriate for the detection of the distinctive signatures of the biomolecules. In this work, we established a standard methodology to detect and discriminate between abiotic and biotic processes in ice grains from extraterrestrial water environments.&#160;References:[1] Postberg et al. (2018) Nature 558, 564-568, [2] Khawaja et al. (2019) Mon Not R Astron Soc 489, 5231-5243, [3] Klenner et al. (2019) Rapid Commun Mass Spectrom 33, 1751-1760, [4] Klenner et al. (2020a) Astrobiology 20, in press, [5] Klenner et al. (2020b) Astrobiology, under review

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REMOTE SENSING OBSERVATIONS AND NUMERICAL SIMULATION FOR MARTIAN LAYERED EJECTA CRATERS

ISPRS - International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences ◽

10.5194/isprs-archives-xlii-3-865-2018 ◽

2018 ◽

Vol XLII-3 ◽

pp. 865-870

Author(s):

L. Li ◽

Z. Yue ◽

C. Zhang ◽

D. Li

Keyword(s):

Remote Sensing ◽

Numerical Simulation ◽

Morphological Characteristics ◽

Subsurface Water ◽

Icy Satellites ◽

Martian Surface ◽

Water Ice ◽

Topographic Features ◽

Model Setup ◽

Basaltic Crust

To understand past Martian climates, it is important to know the distribution and nature of water ice on Mars. Impact craters are widely used ubiquitous indicators for the presence of subsurface water or ice on Mars. Remote sensing observations and numerical simulation are powerful tools for investigating morphological and topographic features on planetary surfaces, and we can use the morphology of layered ejecta craters and hydrocode modeling to constrain possible layering and impact environments. The approach of this work consists of three stages：Firstly, the morphological characteristics of the Martian layered ejecta craters are performed based on Martian images and DEM data. Secondly, numerical modeling layered ejecta are performed through the hydrocode iSALE (impact-SALE). We present hydrocode modeling of impacts onto targets with a single icy layer within an otherwise uniform basalt crust to quantify the effects of subsurface H2O on observable layered ejecta morphologies. The model setup is based on a layered target made up of a regolithic layer (described by the basalt ANEOS), on top an ice layer (described by ANEOS equation of H2O ice), in turn on top of an underlying basaltic crust. The bolide is a 0.8&thinsp;km diameter basaltic asteroid hitting the Martian surface vertically at a velocity of 12.8&thinsp;km/s. Finally, the numerical results are compared with the MOLA DEM profile in order to analyze the formation mechanism of Martian layered ejecta craters. Our simulations suggest that the presence of an icy layer significantly modifies the cratering mechanics, and many of the unusual features of SLE craters may be explained by the presence of icy layers. Impact cratering on icy satellites is significantly affected by the presence of subsurface H2O.

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Variation of the sticking of methanol on low-temperature surfaces as a possible obstacle to freeze out in dark clouds

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa862 ◽

2020 ◽

Vol 494 (3) ◽

pp. 4119-4129

Author(s):

K A K Gadallah ◽

A Sow ◽

E Congiu ◽

S Baouche ◽

F Dulieu

Keyword(s):

Low Temperature ◽

Surface Temperature ◽

Gas Phase ◽

Amorphous Solid ◽

Vacuum System ◽

Initial Value ◽

Water Ice ◽

Dark Clouds ◽

Reflection Absorption Infrared Spectroscopy ◽

Temperature Programmed

ABSTRACT Sticking of gas-phase methanol on different cold surfaces – gold, 13CO, and amorphous solid water (ASW) ice – was studied as a function of surface temperature (7–40 K). In an ultrahigh-vacuum system, reflection absorption infrared spectroscopy (RAIRS) and temperature-programmed desorption methods were simultaneously used to measure methanol sticking efficiency. Methanol band strengths obtained by RAIRS vary greatly depending on the type of the surface. Nevertheless, both methods indicate that the sticking of methanol on different surfaces varies with surface temperature. The sticking efficiency decreases by 30${{\ \rm per\ cent}}$ as the surface temperature goes from 7 to 16 K, then gradually increases until the temperature is 40 K, reaching approximately the initial value found at 7 K. The sticking of methanol differs slightly from one surface to another. At low temperature, it has the lowest values on gold, intermediate values on water ice, and the highest values are found on CO ice, although these differences are smaller than those observed with temperature variation. There exists probably a turning point during the structural organization of methanol ice at 16 K, which makes the capture of methanol from the gas phase less efficient. We wonder if this observation could explain the surprising high abundance of gaseous methanol observed in dense interstellar cores, where it should accrete on grains. In this regard, a 30${{\ \rm per\ cent}}$ reduction of the sticking is not sufficient in itself but transposed to astrophysical conditions dominated by cold gas (∼15 K), which could reduce the sticking efficiency by two orders of magnitude.

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The 3.1 μm absorption feature on asteroids (24) Themis and (65) Cybele is not due to surface water ice

10.5194/epsc2021-796 ◽

2021 ◽

Author(s):

Laurence O'Rourke ◽

Thomas G. Müller ◽

Nicolas Biver ◽

Dominique Bockelée-Morvan ◽

Sunao Hasegawa ◽

...

Keyword(s):

Surface Water ◽

Line Emission ◽

Thermal Inertia ◽

Infrared Camera ◽

Far Infrared ◽

Subsurface Water ◽

Absorption Feature ◽

Water Ice ◽

V Band ◽

Thermophysical Model

Previous research on Asteroids (24) Themis and (65) Cybele have shown the presence of an absorption feature at 3.1 &#956;m reported to be directly linked to surface water ice. We searched for water vapor escaping from these asteroids with the Herschel Space Observatory HIFI (Heterodyne Instrument for the Far Infrared) Instrument. While no H2O line emission was detected, we obtained sensitive 3&#963; water production rate upper limits of Q(H2O)< 4.1&#215;1026 molecules s&#8722;1 for Themis and Q(H2O) <7.6 &#215; 1026 molecules s&#8722;1 for the case of Cybele. Using a thermophysical model, we merged data from the Subaru/Cooled Mid-Infrared Camera and Spectrometer and the Herschel SPIRE (Spectral and Photometric Imaging Receiver) instrument with the contents of a multi-observatory database and thus derived new radiometric properties for these two asteroids. For Themis, we obtained a thermal inertia G = 20 +25-10 J m&#8722;2 s&#8722;1/2 K&#8722;1, a diameter 192 +10-7 km, and a geometric V-band albedo pV=0.07&#177;0.01. For Cybele, we found a thermal inertia G = 25+28-19 J m&#8722;2 s&#8722;1/2 K&#8722;1, a diameter 282&#177;9 km, and an albedo pV=0.042&#177;0.005. Using all inputs, we estimated that water ice intimately mixed with the asteroids&#8217; dark surface material would cover <0.0017% (for Themis) and <0.0033% (for Cybele) of their surfaces, while an areal mixture with very clean ice (Bond albedo 0.8 for Themis and 0.7 for Cybele) would cover <2.2% (for Themis) and <1.5% (for Cybele) of their surfaces. Based on these very low percentage coverage values, it is clear that while surface (and subsurface) water ice may exist in small localized amounts on both asteroids, it is not the reason for the observed 3.1 &#956;m absorption feature.

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Looking for Non-Polar Shallow Subsurface Water Ice in Preparation for Future Human Exploration of Mars

10.5194/epsc2021-443 ◽

2021 ◽

Author(s):

German Martinez ◽

Antonio Segura ◽

Michael D. Smith ◽

Erik Fischer ◽

Nilton O. Renno

Keyword(s):

Subsurface Water ◽

Water Ice ◽

Shallow Subsurface ◽

Human Exploration

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Chemistry and accretion history of Mars

Philosophical Transactions of the Royal Society of London Series A Physical and Engineering Sciences ◽

10.1098/rsta.1994.0132 ◽

1994 ◽

Vol 349 (1690) ◽

pp. 285-293 ◽

Cited By ~ 148

Keyword(s):

Bulk Composition ◽

Volcanic Gases ◽

Martian Surface ◽

Volatile Elements ◽

Water Ice ◽

The Earth ◽

History Of ◽

The Mean ◽

Wet Climate ◽

Martian Regolith

Using element correlations observed in SNC meteorites and general cosmochemical constraints, Wänke & Dreibus (1988) have estimated the bulk composition of Mars. The mean abundance value for moderately volatile elements Na, P, K, F, and Rb and most of the volatile elements like Cl, Br, and I in the Martian mantle exceed the terrestrial values by about a factor of two. The striking depletion of all elements with chalcophile character (Cu, Co, Ni, etc.) indicates that Mars, contrary to the Earth, accreted homogeneously, which also explains the obvious low abundance of water and carbon. SNC meteorites and especially the shergottites are very dry rocks, they also contain very little carbon, while the concentrations of chlorine and especially sulphur are higher than those in terrestrial rocks. As a consequence we should expect SO 2 and HC1 to be the most abundant compounds in Martian volcanic gases. This might explain the dominance of sulphur and chlorine in the Viking soils. In turn SO 2 , being an excellent greenhouse gas, may have been of major importance for the warm and wet period in the ancient Martian history. Episodic release of larger quantities of SO 2 stored in liquid or solid SO 2 tables in the Martian regolith triggered by volcanic intrusions as suggested here could lead to a large number of warm and wet climate periods of the order of a hundred years, interrupted by much longer cold periods characterized by water ice and liquid of solid SO 2 . Sulphur (FeS) probably also governs the oxygen fugacity of the Martian surface rocks.

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Water Ice at Mid-Latitudes on Mars

Oxford Research Encyclopedia of Planetary Science ◽

10.1093/acrefore/9780190647926.013.239 ◽

2021 ◽

Author(s):

Frances E. G. Butcher

Keyword(s):

Climate Changes ◽

Planetary Science ◽

Subsurface Water ◽

Forthcoming Article ◽

Neutron Spectrometer ◽

Near Surface ◽

Water Ice ◽

Orbital Parameters ◽

Imaging Science ◽

Surface Ice

This is an advance summary of a forthcoming article in the Oxford Research Encyclopedia of Planetary Science. Please check back later for the full article. Mars’ mid-latitudes (roughly 30–60° N and S) host voluminous deposits of water ice in the subsurface. At present, perennial water ice cannot exist at the surface in these regions. This is because, for a significant portion of the Martian year, surface temperatures exceed the sublimation point of water ice under Mars’ low atmospheric pressure. Therefore, any seasonal water-ice frost that accumulates in winter sublimates back into the atmosphere in spring. However, a centimeters-to-meters-thick covering of lithic material can inhibit sublimation sufficiently to allow perennial stability of ice in the subsurface. Perennial ice in Mars’ mid-latitudes exists as pore-ice and excess-ice lenses within the regolith, and as massive accumulations of buried, high-purity ice akin to debris-covered glaciers on Earth. The ice is thought to range in age from hundreds of thousands to many hundreds of millions of years old. Its emplacement and modification has been widely attributed to cyclical climate changes induced by variations in Mars’ orbital parameters (primarily its axial tilt). Water ice in Mars’ mid-latitudes is therefore of significant interest for reconstructing such climate changes. It could also provide an essential in situ supply of water for future human missions to Mars. It is possible to infer the presence of water ice in Mars’ subsurface without direct imaging of the ice itself. For example, the distribution of near-surface ice was mapped using Mars Odyssey Neutron Spectrometer detections to calculate the percentage of water-equivalent hydrogen in the upper 1 m of the regolith. Orbital images have revealed a great diversity of ice-related landforms which suggest flow, thermal cycling, sublimation, and disruption (e.g. by impact cratering) of subsurface ice. In some locations, orbital ground-penetrating radar observations have been used to confirm subsurface ice content in areas where its presence has been inferred from the geomorphology of the surface. Water ice in Mars’ mid-latitudes has also been imaged directly by landed and orbital missions. The Phoenix lander exposed water-ice lenses just centimeters beneath the surface, in trenches that it excavated at 68 °N latitude. Orbital images from the High Resolution Imaging Science Experiment (HiRISE) camera on board Mars Reconnaissance Orbiter revealed transient bright ice deposits exhumed by small, fresh impacts into mid-latitude terrains, and ~100 m-high scarps of water ice in exposures through debris-covered ice deposits. In all these cases, the exposed ice has been observed to lose mass by sublimation over time. This demonstrates the essential role of lithic cover in preserving subsurface water ice in Mars’ mid-latitudes.

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Evidence for subsurface water ice in Korolev crater, Mars

Icarus ◽

10.1016/j.icarus.2004.10.032 ◽

2005 ◽

Vol 174 (2) ◽

pp. 360-372 ◽

Cited By ~ 30

Author(s):

John C. Armstrong ◽

Timothy N. Titus ◽

Hugh H. Kieffer

Keyword(s):

Subsurface Water ◽

Water Ice

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