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1. Investigating the stability of aromatic carboxylic acids in hydrated magnesium sulfate under UV irradiation to assist detection of organics on Mars

Author

Andrew Alberini, Teresa Fornaro, Cristina García-Florentino, Malgorzata Biczysko, Iratxe Poblacion, Julene Aramendia, Juan Manuel Madariaga, Giovanni Poggiali, Álvaro Vicente-Retortillo, Kathleen C. Benison, Sandra Siljeström, Sole Biancalani, Christian Lorenz, Edward A. Cloutis, Dan M. Applin, Felipe Gómez, Andrew Steele, Roger C. Wiens, Kevin P. Hand, and John R. Brucato

Subjects
Aromatic organic compounds, FTIR spectroscopy, UV irradiation, Signs of biological activity, Mars 2020 Perseverance mission, Medicine, Science
Abstract

Abstract The Scanning Habitable Environments with Raman and Luminescence for Organics and Chemicals (SHERLOC) instrument onboard the Mars 2020 Perseverance rover detected so far some of the most intense fluorescence signals in association with sulfates analyzing abraded patches of rocks at Jezero crater, Mars. To assess the plausibility of an organic origin of these signals, it is key to understand if organics can survive exposure to ambient Martian UV after exposure by the Perseverance abrasion tool and prior to analysis by SHERLOC. In this work, we investigated the stability of organo-sulfate assemblages under Martian-like UV irradiation and we observed that the spectroscopic features of phthalic and mellitic acid embedded into hydrated magnesium sulfate do not change for UV exposures corresponding to at least 48 Martian sols and, thus, should still be detectable in fluorescence when the SHERLOC analysis takes place, thanks to the photoprotective properties of magnesium sulfate. In addition, different photoproduct bands diagnostic of the parent carboxylic acid molecules could be observed. The photoprotective behavior of hydrated magnesium sulfate corroborates the hypothesis that sulfates might have played a key role in the preservation of organics on Mars, and that the fluorescence signals detected by SHERLOC in association with sulfates could potentially arise from organic compounds.

Published
2024
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2. Spectral evidence for irradiated halite on Mars

Author

Michael S. Bramble and Kevin P. Hand

Subjects
Medicine, Science
Abstract

Abstract The proposed chloride salt-bearing deposits on Mars have an enigmatic composition due to the absence of distinct spectral absorptions for the unique mineral at all wavelengths investigated. We report on analyses of remote visible-wavelength spectroscopic observations that exhibit properties indicative of the mineral halite (NaCl) when irradiated. Visible spectra of halite are generally featureless, but when irradiated by high-energy particles they develop readily-identifiable spectral alterations in the form of color centers. Consistent spectral characteristics observed in the reflectance data of the chloride salt-bearing deposits support the presence of radiation-formed color centers of halite on the surface of Mars. We observe a seasonal cycle of color center formation with higher irradiated halite values during winter months, with the colder temperatures interpreted as increasing the formation efficiency and stability. Irradiated halite identified on the surface of Mars suggests that the visible surface is being irradiated to the degree that defects are forming in alkali halide crystal structures.

Published
2024
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3. JWST Reveals CO Ice, Concentrated CO2 Deposits, and Evidence for Carbonates Potentially Sourced from Ariel’s Interior

Author

Richard J. Cartwright, Bryan J. Holler, William M. Grundy, Stephen C. Tegler, Marc Neveu, Ujjwal Raut, Christopher R. Glein, Tom A. Nordheim, Joshua P. Emery, Julie C. Castillo-Rogez, Eric Quirico, Silvia Protopapa, Chloe B. Beddingfield, Matthew M. Hedman, Katherine de Kleer, Riley A. DeColibus, Anastasia N. Morgan, Ryan Wochner, Kevin P. Hand, Geronimo L. Villanueva, Sara Faggi, Noemi Pinilla-Alonso, David E. Trilling, and Michael M. Mueller

Subjects
Carbon dioxide, Ice spectroscopy, Surface ices, Surface processes, Surface composition, James Webb Space Telescope, Astrophysics, QB460-466
Abstract

The Uranian moon Ariel exhibits a diversity of geologically young landforms, with a surface composition rich in CO _2 ice. The origin of CO _2 and other species, however, remains uncertain. We report observations of Ariel’s leading and trailing hemispheres, collected with NIRSpec (2.87–5.10 μ m) on the James Webb Space Telescope. These data shed new light on Ariel's spectral properties, revealing a double-lobed CO _2 ice scattering peak centered near 4.20 and 4.25 μ m, with the 4.25 μ m lobe possibly representing the largest CO _2 Fresnel peak yet observed in the solar system. A prominent 4.38 μ m ^13 CO _2 ice feature is also present, as is a 4.90 μ m band that results from ^12 CO _2 ice. The spectra reveal a 4.67 μ m ^12 CO ice band and a broad 4.02 μ m band that might result from carbonate minerals. The data confirm that features associated with CO _2 and CO are notably stronger on Ariel’s trailing hemisphere compared to its leading hemisphere. We compared the detected CO _2 features to synthetic spectra of CO _2 ice and mixtures of CO _2 with CO, H _2 O, and amorphous carbon, finding that CO _2 could be concentrated in deposits thicker than ∼10 mm on Ariel’s trailing hemisphere. Comparison to laboratory data indicates that CO is likely mixed with CO _2 . The evidence for thick CO _2 ice deposits and the possible presence of carbonates on both hemispheres suggests that some carbon oxides could be sourced from Ariel’s interior, with their surface distributions modified by charged particle bombardment, sublimation, and seasonal migration of CO and CO _2 from high to low latitudes.

Published
2024
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4. Revealing Callisto’s Carbon-rich Surface and CO2 Atmosphere with JWST

Author

Richard J. Cartwright, Geronimo L. Villanueva, Bryan J. Holler, Maria Camarca, Sara Faggi, Marc Neveu, Lorenz Roth, Ujjwal Raut, Christopher R. Glein, Julie C. Castillo-Rogez, Michael J. Malaska, Dominique Bockelée-Morvan, Tom A. Nordheim, Kevin P. Hand, Giovanni Strazzulla, Yvonne J. Pendleton, Katherine de Kleer, Chloe B. Beddingfield, Imke de Pater, Dale P. Cruikshank, and Silvia Protopapa

Subjects
Infrared spectroscopy, Galilean satellites, Callisto, James Webb Space Telescope, Natural satellite atmospheres, Natural satellite surfaces, Astronomy, QB1-991
Abstract

We analyzed spectral cubes of Callisto’s leading and trailing hemispheres, collected with the NIRSpec Integrated Field Unit (G395H) on the James Webb Space Telescope. These spatially resolved data show strong 4.25 μ m absorption bands resulting from solid-state ^12 CO _2 , with the strongest spectral features at low latitudes near the center of its trailing hemisphere, consistent with radiolytic production spurred by magnetospheric plasma interacting with native H _2 O mixed with carbonaceous compounds. We detected CO _2 rovibrational emission lines between 4.2 and 4.3 μ m over both hemispheres, confirming the global presence of CO _2 gas in Callisto’s tenuous atmosphere. These results represent the first detection of CO _2 gas over Callisto’s trailing side. The distribution of CO _2 gas is offset from the subsolar region on either hemisphere, suggesting that sputtering, radiolysis, and geologic processes help sustain Callisto’s atmosphere. We detected a 4.38 μ m absorption band that likely results from solid-state ^13 CO _2 . A prominent 4.57 μ m absorption band that might result from CN-bearing organics is present and significantly stronger on Callisto’s leading hemisphere, unlike ^12 CO _2 , suggesting these two spectral features are spatially antiassociated. The distribution of the 4.57 μ m band is more consistent with a native origin and/or accumulation of dust from Jupiter’s irregular satellites. Other, more subtle absorption features could result from CH-bearing organics, CO, carbonyl sulfide, and Na-bearing minerals. These results highlight the need for preparatory laboratory work and improved surface–atmosphere interaction models to better understand carbon chemistry on the icy Galilean moons before the arrival of NASA’s Europa Clipper and ESA’s JUICE spacecraft.

Published
2024
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5. Distinct Microbial Assemblage Structure and Archaeal Diversity in Sediments of Arctic Thermokarst Lakes Differing in Methane Sources

Author

Paula B. Matheus Carnevali, Craig W. Herbold, Kevin P. Hand, John C. Priscu, and Alison E. Murray

Subjects
methane, thermokarst, lake, sediments, Arctic, Alaska, Microbiology, QR1-502
Abstract

Developing a microbial ecological understanding of Arctic thermokarst lake sediments in a geochemical context is an essential first step toward comprehending the contributions of these systems to greenhouse gas emissions, and understanding how they may shift as a result of long term changes in climate. In light of this, we set out to study microbial diversity and structure in sediments from four shallow thermokarst lakes in the Arctic Coastal Plain of Alaska. Sediments from one of these lakes (Sukok) emit methane (CH4) of thermogenic origin, as expected for an area with natural gas reserves. However, sediments from a lake 10 km to the North West (Siqlukaq) produce CH4 of biogenic origin. Sukok and Siqlukaq were chosen among the four lakes surveyed to test the hypothesis that active CH4-producing organisms (methanogens) would reflect the distribution of CH4 gas levels in the sediments. We first examined the structure of the little known microbial community inhabiting the thaw bulb of arctic thermokarst lakes near Barrow, AK. Molecular approaches (PCR-DGGE and iTag sequencing) targeting the SSU rRNA gene and rRNA molecule were used to profile diversity, assemblage structure, and identify potentially active members of the microbial assemblages. Overall, the potentially active (rRNA dominant) fraction included taxa that have also been detected in other permafrost environments (e.g., Bacteroidetes, Actinobacteria, Nitrospirae, Chloroflexi, and others). In addition, Siqlukaq sediments were unique compared to the other sites, in that they harbored CH4-cycling organisms (i.e., methanogenic Archaea and methanotrophic Bacteria), as well as bacteria potentially involved in N cycling (e.g., Nitrospirae) whereas Sukok sediments were dominated by taxa typically involved in photosynthesis and biogeochemical sulfur (S) transformations. This study revealed a high degree of archaeal phylogenetic diversity in addition to CH4-producing archaea, which spanned nearly the phylogenetic extent of currently recognized Archaea phyla (e.g., Euryarchaeota, Bathyarchaeota, Thaumarchaeota, Woesearchaeota, Pacearchaeota, and others). Together these results shed light on expansive bacterial and archaeal diversity in Arctic thermokarst lakes and suggest important differences in biogeochemical potential in contrasting Arctic thermokarst lake sediment ecosystems.

Published
2018
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6. Overview and Results From the Mars 2020 Perseverance Rover's First Science Campaign on the Jezero Crater Floor

Author

Vivian Z. Sun, Kevin P. Hand, Kathryn M. Stack, Ken A. Farley, Justin I. Simon, Claire Newman, Sunanda Sharma, Yang Liu, Roger C. Wiens, Amy J. Williams, Nicholas Tosca, Sanna Alwmark, Olivier Beyssac, Adrian Brown, Fred Calef, Emily L. Cardarelli, Elise Clavé, Barbara Cohen, Andrea Corpolongo, Andrew D. Czaja, Tyler Del Sesto, Alberto Fairen, Teresa Fornaro, Thierry Fouchet, Brad Garczynski, Sanjeev Gupta, Chris D. K. Herd, Keyron Hickman-Lewis, Briony Horgan, Jeffrey Johnson, Kjartan Kinch, Tanya Kizovski, Rachel Kronyak, Robert Lange, Lucia Mandon, Sarah Milkovich, Robert Moeller, Jorge Núñez, Gerhard Paar, Guy Pyrzak, Cathy Quantin-Nataf, David L. Shuster, Sandra Siljestroem, Andrew Steele, Michael Tice, Olivier Toupet, Arya Udry, Alicia Vaughan, and Brittan Wogsland

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Mars 2020 Perseverance rover landed in Jezero crater on 18 February 2021. After a 100-sol period of commissioning and the Ingenuity Helicopter technology demonstration, Perseverance began its first science campaign to explore the enigmatic Jezero crater floor, whose igneous or sedimentary origins have been much debated in the scientific community. This paper describes the campaign plan developed to explore the crater floor's Máaz and Séítah formations and summarizes the results of the campaign between sols 100–379. By the end of the campaign, Perseverance had traversed more than 5 km, created seven abrasion patches, and sealed nine samples and a witness tube. Analysis of remote and proximity science observations show that the Máaz and Séítah formations are igneous in origin and composed of five and two geologic members, respectively. The Séítah formation represents the olivine-rich cumulate formed from differentiation of a slowly cooling melt or magma body, and the Máaz formation likely represents a separate series of lava flows emplaced after Séítah. The Máaz and Séítah rocks also preserve evidence of multiple episodes of aqueous alteration in secondary minerals like carbonate, Fe/Mg phyllosilicates, sulfates, and perchlorate, and surficial coatings. Post-emplacement processes tilted the rocks near the Máaz-Séítah contact and substantial erosion modified the crater floor rocks to their present-day expressions. Results from this crater floor campaign, including those obtained upon return of the collected samples, will help to build the geologic history of events that occurred in Jezero crater and provide time constraints on the formation of the Jezero delta.

Published
2023
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8. A continuum of icy satellites’ radar properties explained by the coherent backscatter effect

Author

Jason D. Hofgartner and Kevin P. Hand

Subjects
Astronomy and Astrophysics
Abstract

The radar properties of icy satellites of Jupiter and Saturn commonly differ by more than an order of magnitude from those of rocky planets because of the lower absorptivity of water ice than that of rock. However, the specific mechanisms behind these differences are not confidently known yet. Here we show that the global radar albedos and the circular polarization ratios of icy satellites are correlated and vary together along a continuum, which is not satisfactorily explained by existing models. We modified a backscatter model that includes the coherent backscatter opposition effect (CBOE) and found that it fits successfully the observed continuum, indicative of CBOE’s primary role in driving the circular polarization ratios of icy satellites. We predict that the linear polarization ratios and the incidence angle variation properties also vary along the observed continuum, and that, globally, Europa and Enceladus have very heterogeneous surfaces/subsurfaces with very little microwave absorption. The modified CBOE model suggests that some worlds beyond Saturn’s orbit that are rich in non-water ices may have even more extreme radar properties.

Published
2023

9. Perseverance’s Scanning Habitable Environments with Raman and Luminescence for Organics and Chemicals (SHERLOC) Investigation

Author

Rohit Bhartia, Luther W Beegle, Lauren DeFlores, William J Abbey, Joseph Razzell Hollis, Kyle Uckert, Brian Monacelli, Kenneth S Edgett, Megan R Kennedy, Margarite Sylvia, David Aldrich, Mark S Anderson, Sanford A Asher, Zachary J Bailey, Kerry Boyd, Aaron S Burton, Michael Caffrey, Michael J Calaway, Robert J Calvet, Bruce A Cameron, Michael A Caplinger, Brandi Carrier, Natalie Chen, Amy C Chen, Matthew J Clark, Samuel M Clegg, Pamela G Conrad, Moogega Cooper, Kristine N Davis, Bethany L Ehlmann, Linda J Facto, Marc D Fries, Daniel H Garrison, Denine Gasway, F Tony Ghaemi, Trevor G Graff, Kevin P Hand, Cathleen Harris, Jeffrey D Hein, Nicholas Heinz, Harrison Herzog, Eric B Hochberg, Andrew Houck, William F Hug, Elsa H Jensen, Linda Christine Kah, John A Kennedy, Robert Krylo, Johnathan Lam, Mark A Lindeman, Justin McGlown, John Michel, Ed Miller, Zachary Mills, Michelle E Minitti, Fai Mok, James D Moore, Kenneth H Nealson, Anthony Nelson, Raymond Newell, Brian E Nixon, Daniel A Nordman, Danielle L Nuding, Sonny M Orellana, Michael T Pauken, Glen Peterson, Randy Pollock, Heather Quinn, Claire Quinto, Michael A Ravine, Ray D Reid, Joe Riendeau, Amy J Ross, Joshua Sackos, Jacob A Schaffner, Mark A Schwochert, Molly O Shelton, Rufus Simon, Caroline L Smith, Pablo Sobron, Kimberly B Steadman, Andrew Steele, Dave Thiessen, Vinh D Tran, Tony Tsai, Michael Tuite, Eric Tung, Rami A Wehbe, Rachael Weinberg, Ryan H Weiner, Roger C Weins, Kenneth Williford, Chris Wollonciej, Yen-Hung Wu, R Aileen Yingst, and Jason A Zan

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Scanning Habitable Environments with Raman and Luminescence for Organics and Chemicals (SHERLOC) is a robotic arm-mounted instrument on NASA’s Perseverance rover. SHERLOC has two primary boresights. The Spectroscopy boresight generates spatially resolved chemical maps using fluorescence and Raman spectroscopy coupled to microscopic images (10.1 μm/pixel). The second boresight is a Wide Angle Topographic Sensor for Operations and eNgineering (WATSON); a copy of the Mars Science Laboratory (MSL) Mars Hand Lens Imager (MAHLI) that obtains color images from microscopic scales (∼13 μm/pixel) to infinity. SHERLOC Spectroscopy focuses a 40 μs pulsed deep UV neon-copper laser (248.6 nm), to a ∼100 μm spot on a target at a working distance of ∼48 mm. Fluorescence emissions from organics, and Raman scattered photons from organics and minerals, are spectrally resolved with a single diffractive grating spectrograph with a spectral range of 250 to ∼370 nm. Because the fluorescence and Raman regions are naturally separated with deep UV excitation (<250 nm), the Raman region ∼ 800 – 4000 cm−1 (250 to 273 nm) and the fluorescence region (274 to ∼370 nm) are acquired simultaneously without time gating or additional mechanisms. SHERLOC science begins by using an Autofocus Context Imager (ACI) to obtain target focus and acquire 10.1 μm/pixel greyscale images. Chemical maps of organic and mineral signatures are acquired by the orchestration of an internal scanning mirror that moves the focused laser spot across discrete points on the target surface where spectra are captured on the spectrometer detector. ACI images and chemical maps (< 100 μm/mapping pixel) will enable the first Mars in situ view of the spatial distribution and interaction between organics, minerals, and chemicals important to the assessment of potential biogenicity (containing CHNOPS). Single robotic arm placement chemical maps can cover areas up to 7x7 mm in area and, with the < 10 min acquisition time per map, larger mosaics are possible with arm movements. This microscopic view of the organic geochemistry of a target at the Perseverance field site, when combined with the other instruments, such as Mastcam-Z, PIXL, and SuperCam, will enable unprecedented analysis of geological materials for both scientific research and determination of which samples to collect and cache for Mars sample return.

Published
2021
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10. Evidence for Ammonia-bearing Species on the Uranian Satellite Ariel Supports Recent Geologic Activity

Author

Richard J. Cartwright, Chloe B. Beddingfield, Tom A. Nordheim, Joseph Roser, William M. Grundy, Kevin P. Hand, Joshua P. Emery, Dale P Cruikshank, and Francesca Scipioni

Subjects
Geosciences (General)
Abstract

We investigated whether ammonia-rich constituents are present on the surface of the Uranian moon Ariel by analyzing 32 near-infrared reflectance spectra collected over a wide range of sub-observer longitudes and latitudes. We measured the band areas and depths of a 2.2 μm feature in these spectra, which has been attributed to ammonia-bearing species on other icy bodies. Ten spectra display prominent 2.2 μm features with band areas and depths >2σ. We determined the longitudinal distribution of the 2.2 μm band, finding no statistically meaningful differences between Ariel’s leading and trailing hemispheres, indicating that this band is distributed across Ariel’s surface. We compared the band centers and shapes of the five Ariel spectra displaying the strongest 2.2 μm bands to laboratory spectra of various ammonia-bearing and ammonium-bearing species, finding that the spectral signatures of the Ariel spectra are best matched by ammonia-hydrates and flash frozen ammonia-water solutions. Our analysis also revealed that four Ariel spectra display 2.24 μm bands (>2σ band areas and depths), with band centers and shapes that are best matched by ammonia ice. Because ammonia should be efficiently removed over short timescales by ultraviolet photons, cosmic rays, and charged particles trapped in Uranus’ magnetosphere, the possible presence of this constituent supports geologic activity in the recent past, such as emplacement of ammonia-rich cryolavas and exposure of ammonia-rich deposits by tectonism, impact events, and mass wasting.

Published
2020
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15. Life beneath an icy moon

Author

Kevin P. Hand

Subjects
Solar System, Multidisciplinary, Extraterrestrial life, Harbour, Satellite, Icy moon, computer, Geology, Astrobiology, computer.programming_language
Abstract

The frigid satellite worlds of our outer solar system may harbour extraterrestrial life. Planetary scientist Kevin Hand tells Daniel Cossins his plan to find it

Published
2020

20. Analogue experiments for the identification of organics in ice grains from Europa using mass spectrometry

Author

Maryse Napoleoni, Fabian Klenner, Jon K. Hillier, Nozair Khawaja, Kevin P. Hand, and Frank Postberg

Abstract

Jupiter’s moon Europa is predicted to harbor a global liquid water ocean beneath its icy crust [1,2]. Like Saturn’s moon Enceladus, Europa could be cryovolcanically active, with evidence for plumes of water recently reported (e.g. [3,4]). Such plumes could eject gas and water ice grains from the subsurface ocean into space. Sputtering and micrometeorite bombardment may also eject icy surface particles to high altitudes [5]. Ice grains ejected from icy moons can be analyzed during spacecraft flybys by impact ionization mass spectrometers [6], such as the Cosmic Dust Analyzer (CDA) onboard the Cassini spacecraft or the Surface Dust Analyzer (SUDA) that will be onboard the upcoming Europa Clipper mission [7]. These instruments can determine the composition of the ice grains and potentially indirectly sample subsurface oceans. In the Saturnian system, data collected by the CDA instrument showed that Enceladus’ interior ocean is salt-rich [8], sustains water-rock hydrothermal interactions [9], and contains a variety of organic material, including complex macromolecules [10] and low mass volatile compounds, potentially acting as amino acid precursors [11]. On Europa, the subsurface ocean is predicted to be in direct contact with silicates and possible seafloor magmatic activity, enhancing the potential habitability of the moon [12]. The moon’s surface is also exposed to the harsh radiation environment of Jupiter, which may induce oxidation and potentially other chemical reactions involving both ice and non-ice compounds [13]. Interpreting mass spectra acquired in space requires terrestrial calibration by analogue experiments. The Laser Induced Liquid Beam Ion Desorption (LILBID) technique reproduces the impact ionization mass spectra of ice grains recorded in space [14]. Previous LILBID experiments have shown that bioessential molecules, such as amino acids and fatty acids, can be detected in ice grains at concentrations as low as the µM or nM level [15], and that the abiotic and biotic formation processes of these molecules can be distinguished from each other based on spectral features [16]. Microbial biosignatures were also investigated recently, showing that nucleobases, fatty acids and other bacterial fragments can be clearly identified [17]. Here we investigate whether Europa-relevant organic compounds encased in ice grains can also be detected and characterized using impact ionization mass spectrometry in space. High-sensitivity LILBID experiments have been performed with formamide (CH3NO), farnesol (C15H26O), cholesteryl linoleate (C45H76O2) and N-dodecanoyl-L-homoserine lactone (C16H29NO3) to predict their spectral appearance in both anion and cation mass spectra. Formamide is expected to form by radiolytic reactions on Europa’s surface [18], while farnesol, cholesteryl linoleate and N-dodecanoyl-L-homoserine lactone are lipids, representing potential biosignatures and selected for their high resistance to degradation. These compounds were investigated in water matrices with varying NaCl concentrations designed to mimic Europa’s predicted salty ocean and surface composition [19,20]. Results show that the identification of molecular peaks as well as characteristic fragments is possible for both formamide and lipids. Additionally, the spectra of formamide in salt-rich matrices show that formamide can be detected via sodiated molecular clusters ([CH3NO+Na]+) and other Na-rich complexes. The next steps will be to investigate these compounds in H2O2-rich matrices, designed to simulate the highly oxidizing surface environment of Europa [21]. Sulfate salts and sulfuric acid are also under consideration as important matrices relevant to the surface chemistry of Europa. Other potential biosignatures, as well as their irradiation products, will be investigated to study the likelihood of their survival and detection under Europa’s radiation environment. The recorded mass spectra will complement a comprehensive spectral reference library [22], which provides analogue data of a wide range of compounds applicable to impact ionization mass spectrometers onboard Europa Clipper or other future ocean world missions. References [1] Kivelson et al. (2000) Science 289.5483: 1340-1343 [2] Zimmer et al. (2000) Icarus 147.2: 329-347 [3] Jia et al. (2018) Nature Astronomy volume 2, pages 459–464 [4] Roth et al. (2014) Science 343.6167: 171-174. [5] Miljkovic et al. (2012), Planetary and Space Science 70.1: 20-27 [6] Postberg, et al. (2011) Planetary and Space Science 59.14: 1815-1825 [7] Kempf et al. (2014) EPSC2014-229, 2014 [8] Postberg et al. (2009) Nature 459.7250: 1098-1101 [9] Hsu et al. (2005) Nature 519.7542: 207-210 [10] Postberg et al. (2018) Nature 558:564–568 [11] Khawaja et al. (2019) Mon Not R Astron Soc 489:5231–5243 [12] Hand et al. (2009) Europa 589-629. [13] Hand et al. (2007) Astrobiology 7.6: 1006-1022 [14] Klenner et al. (2019) Rapid Commun Mass Spectrom. 33.22: 1751-1760 [15] Klenner et al. (2020) Astrobiology 20:179–189 [16] Klenner et al. (2020) Astrobiology 20: 1168–1184 [17] Pavlista et al. (2021) EGU21-15475 [18] Hand (2007) PhD Thesis, Dpt of Geological and Environmental Sciences, Stanford University [19] Zolotov et al. (2001) Journal of Geophysical Research: Planets 106.E12: 32815-32827 [20] Trumbo et al. (2019) Science advances 5.6: eaaw7123 [21] Johnson et al. (2003) Astrobiology 3, 823–850 [22] Klenner et al., in prep.

Published
2021

21. Science Goals and Objectives for the Dragonfly Titan Rotorcraft Relocatable Lander

Author

Simon Stähler, E. R. Stofan, Kevin P. Hand, C. D. Neish, William B. Brinckerhoff, Colin Wilson, Ralph D. Lorenz, Scot Rafkin, R. A. Yingst, Tetsuya Tokano, Kris Zacny, Jani Radebaugh, Christopher P. McKay, Patrick N. Peplowski, Alexander Hayes, Erich Karkoschka, Juan M. Lora, Jorge I. Nunez, Jason W. Barnes, Claire E. Newman, Melissa G. Trainer, Alice Le Gall, A. M. Parsons, Caroline Freissinet, Mark P. Panning, Lynnae C. Quick, David J. Lawrence, Carolyn M. Ernst, Cyril Szopa, Thomas P. Wagner, Jeffrey R. Johnson, Hiroaki Shiraishi, R. S. Miller, Kristin S. Sotzen, Sarah M. Hörst, Shannon MacKenzie, Elizabeth P. Turtle, Morgan L. Cable, Scott L. Murchie, Jason M. Soderblom, Angela Stickle, Department of Physics [Moscow,USA], University of Idaho [Moscow, USA], Johns Hopkins University Applied Physics Laboratory [Laurel, MD] (APL), NASA Goddard Space Flight Center (GSFC), Jet Propulsion Laboratory (JPL), NASA-California Institute of Technology (CALTECH), PLANETO - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS), Department of Astronomy [Ithaca], Cornell University [New York], Morton K. Blaustein Department of Earth and Planetary Sciences [Baltimore], Johns Hopkins University (JHU), Lunar and Planetary Laboratory [Tucson] (LPL), University of Arizona, Department of Earth and Planetary Sciences [New Haven], Yale University [New Haven], NASA Ames Research Center (ARC), Planetary Science Institute [Tucson] (PSI), Department of Earth Sciences [London, ON], University of Western Ontario (UWO), Aeolis Research, Department of Geological Sciences [BYU], Brigham Young University (BYU), Southwest Research Institute [Boulder] (SwRI), Institute of Space and Astronautical Science (ISAS), Japan Aerospace Exploration Agency [Sagamihara] (JAXA), Department of Earth and Planetary Sciences [Cambridge, USA] (EPS), Harvard University [Cambridge], Smithsonian National Air and Space Museum, Smithsonian Institution, Institut für Geophysik und Meteorologie [Köln], Universität zu Köln, NASA Headquarters, Department of Atmospheric, Oceanic and Planetary Physics [Oxford] (AOPP), University of Oxford [Oxford], Honeybee Robotics Ltd, Institute of Geophysics [ETH Zürich], Department of Earth Sciences [Swiss Federal Institute of Technology - ETH Zürich] (D-ERDW), and Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich)- Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich)

Subjects
Aquifer, 01 natural sciences, Mantle (geology), Astrobiology, Pre-biotic astrochemistry, 03 medical and health sciences, symbols.namesake, Extant taxon, Impact crater, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Planetary surfaces, 14. Life underwater, 010303 astronomy & astrophysics, 030304 developmental biology, 0303 health sciences, geography, geography.geographical_feature_category, Habitability, Astronomy and Astrophysics, Prebiotic chemistry, Geophysics, 13. Climate action, Space and Planetary Science, [SDU]Sciences of the Universe [physics], symbols, Water ice, Titan (rocket family), Titan, Planetary atmospheres
Abstract

NASA’s Dragonfly mission will send a rotorcraft lander to the surface of Titan in the mid-2030s. Dragonfly's science themes include investigation of Titan’s prebiotic chemistry, habitability, and potential chemical biosignatures from both water-based “life as we know it” (as might occur in the interior mantle ocean, potential cryovolcanic flows, and/or impact melt deposits) and potential “life, but not as we know it” that might use liquid hydrocarbons as a solvent (within Titan’s lakes, seas, and/or aquifers). Consideration of both of these solvents simultaneously led to our initial landing site in Titan’s equatorial dunes and interdunes to sample organic sediments and water ice, respectively. Ultimately, Dragonfly's traverse target is the 80 km diameter Selk Crater, at 7° N, where we seek previously liquid water that has mixed with surface organics. Our science goals include determining how far prebiotic chemistry has progressed on Titan and what molecules and elements might be available for such chemistry. We will also determine the role of Titan’s tropical deserts in the global methane cycle. We will investigate the processes and processing rates that modify Titan’s surface geology and constrain how and where organics and liquid water can mix on and within Titan. Importantly, we will search for chemical biosignatures indicative of past or extant biological processes. As such, Dragonfly, along with Perseverance, is the first NASA mission to explicitly incorporate the search for signs of life into its mission goals since the Viking landers in 1976.

Published
2021

23. Penitente formation is unlikely on Europa

Author

Kevin P. Hand, J. Foster, Benjamin Furst, Amy E. Hofmann, Daniel F. Berisford, and Takurou Daimaru

Subjects
General Earth and Planetary Sciences, Geology
Published
2019

24. CITADEL: An Icy Worlds Simulation Testbed

Author

Kristo Kriechbaum, Jay D. Jasper, Kevin P. Hand, Lori Shiraishi, Chris Sercel, Daniel F. Berisford, Eric Roberts, Alex Brinkman, Grayson Adams, Brendan Chamberlain-Simon, David Inkyu Kim, Taku Daimaru, Thomas Green, and Daniel Neamati

Subjects
Computer science, Testbed, Operating system, computer.software_genre, computer
Published
2021

26. Science of the Europa Lander Mission Concept

Author

Alyssa Rhoden, Kevin P. Hand, Kenneth H. Nealson, J. Kosberg, Alexander G. Hayes, Bethany L. Ehlmann, M. L. Cable, Jennifer E.C. Scully, Alison E. Murray, Britney E. Schmidt, Jo Eliza Pitesky, William B. Brinckerhoff, M. E. Cameron, Peter Willis, Jason D. Hofgartner, Tom Nordheim, Emily Klonicki, Jonathan I. Lunine, Brent C. Christner, J. Foster, A. Yingst, K. Edgett, Michael J. Russell, Cynthia B. Phillips, Amy E. Hofmann, Chris Paranicas, David E. Smith, Kate Craft, Tori M. Hoehler, Sarah M. Hörst, James B. Garvin, Alexis S. Templeton, and C. R. German

Subjects
Environmental science
Published
2021

27. Jupiter System Observatory at Sun-Jupiter Lagrangian Point One

Author

François-Xavier Schmider, Kevin P. Hand, Cindy Young, Ricardo Hueso Alonso, Michael H. Wong, Timothy A. Cassidy, Katherine de Kleer, Fran Bagenal, William S. Kurth, Donald G. Mitchell, Gregory T. Delory, Joseph Westlake, Hsiang-Wen Hsu, Imke de Pater, Mihaly Horanyi, Joe Pitman, Constantine Tsang, Bertrand Bonfond, Sascha Kempf, Tracy M. Becker, Frank Postberg, Cesare Grava, Frank Crary, Kunio M. Sayanagi, Zoltan Sternovsky, George Hospodarsky, Amanda R. Hendrix, Daniel Kubitschek, Nicolas Altobelli, Joshua P. Emery, Ashley Davies, Nicholas M. Schneider, Patrick Gaulme, Tristan Guillot, Jeffery Parker, Howard Smith, Wei-Ling Tseng, Glenn S. Orton, Greg Holsclaw, Timothy A. Livengood, and Wing-Huen Ip

Subjects
Jupiter, Physics, Observatory, Jupiter system, Astronomy, Lagrangian point
Published
2021

29. On the Past, Present, and Future Role of Biology in NASA’s Exploration of our Solar System

Author

Frieder Klein, Kakani Katija, Woodward W. Fischer, Marian Carlson, Eric S. Boyd, Cynthia B. Phillips, Susanne Neuer, R. S. Shapiro, Magdalena R. Osburn, Robert M. Hazen, Christopher H. House, Kennda Lynch, Moh El-Naggar, Beth N. Orcutt, Dana Manalang, James Bradley, Donato Giovannelli, Gareth Trubl, Ellie Hara, Jayme Feyhl-Buska, William J. Brazelton, Bradley S. Stevenson, Julie A. Huber, Victoria M. Fulfer, Jennifer E.C. Scully, Gillian H. Gile, Jennifer B. Glass, Alexis S. Templeton, Anne E. Dekas, Paul G. Falkowski, Kate Craft, Victoria J. Orphan, Kirtland J. Robinson, Christopher L. Dupont, Brent C. Christner, Elizabeth Trembath-Reichert, Jason D. Hofgartner, Jill A. Mikucki, Samantha K. Trumbo, Karen G. Lloyd, David A. Fike, Mihaela Glamoclija, Kevin P. Hand, John R. Delaney, Gürol M. Süel, Mónica Sánchez-Román, Amy E. Hofmann, Andrew D. Steen, Rika E. Anderson, John A. Baross, Jo Eliza Pitesky, Joy Buongiorno, Anna-Louise Reysenbach, Colleen M. Cavanaugh, Tom Nordheim, Carolina Reyes, M. E. Cameron, Jeffrey S. Seewald, Alexander S. Bradley, Anaïs Roussel, Jack D. Farmer, Tristan Caro, Johann Peter Gogarten, Ferran Garcia-Pichel, Tori M. Hoehler, Phoebe Cohen, Brandy M. Toner, Karyn L. Rogers, Ariel D. Anbar, Timothy M. Shank, Alison E. Murray, Everett L. Shock, Mark L. Skidmore, Christopher F. Chyba, Michael E. Brown, Ceth W. Parker, Betul Kacar, Steven D'Hondt, Jeffrey Marlow, Douglas H. Bartlett, John R. Spear, Jan P. Amend, and Lynn J. Rothschild

Subjects
Solar System, Systems engineering
Published
2021

30. An Exploration Strategy for Europa

Author

Jo Eliza Pitesky, Tom Nordheim, Cynthia B. Phillips, Amy E. Hofmann, Kate Craft, Kevin P. Hand, Jennifer E.C. Scully, Jason D. Hofgartner, M. E. Cameron, Morgan L. Cable, and Grace H. Tan-Wang

Published
2021

33. Internal-Current Lorentz-Force Heating of Astrophysical Objects

Author

Kevin P. Hand and Christopher F. Chyba

Subjects
Physics, Earth and Planetary Astrophysics (astro-ph.EP), Orbital speed, Field (physics), media_common.quotation_subject, FOS: Physical sciences, Astronomy and Astrophysics, Mechanics, Dissipation, Radial velocity, Jupiter, symbols.namesake, Space and Planetary Science, symbols, Astrophysics::Earth and Planetary Astrophysics, Eccentricity (behavior), Joule heating, Lorentz force, Astrophysics - Earth and Planetary Astrophysics, media_common
Abstract

Two forms of ohmic heating of astrophysical secondaries have received particular attention: unipolar-generator heating with currents running between the primary and secondary; and magnetic induction heating due to the primary's time-varying field. Neither appears to cause significant dissipation in the contemporary solar system. But these discussions have overlooked heating derived from the spatial variation of the primary's field across the interior of the secondary. This leads to Lorentz force-driven currents around paths entirely internal to the secondary, with resulting ohmic heating. We examine three ways to drive such currents, by the cross product of: (1) the secondary's azimuthal orbital velocity with the non-axially symmetric field of the primary; (2) the radial velocity (due to non-zero eccentricity) of the secondary with the primary's field; or (3) the out-of-plane velocity (due to non-zero inclination) with the primary's field. The first of these operates even for a spin-locked secondary whose orbit has zero eccentricity, in strong contrast to tidal dissipation. We show that Jupiter's moon Io today could dissipate about 600 GW (more than likely current radiogenic heating) in the outer hundred meters of its metallic core by this mechanism. Had Io ever been at 3 jovian radii instead of its current 5.9, it could have been dissipating 15,000 GW. Ohmic dissipation provides a mechanism that could operate in any solar system to drive inward migration of secondaries that then necessarily comes to a halt upon reaching a sufficiently close distance to the primary., Comment: 12 pages, 1 figure; accepted for publication in Astrophysical Journal Letters

Published
2021
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34. EUROPA: SCIENCE-DRIVEN PREPARATIONS FOR LANDING ON AN UNKNOWN SURFACE

Author

Kevin P. Hand, Erin Leonard, Cynthia B. Phillips, Emily Klonicki, Amy E. Hofmann, Jason D. Hofgartner, M. E. Cameron, Kathleen L. Craft, Jo Eliza Pitesky, Jennifer E.C. Scully, and Shawn Brooks

Subjects
Surface (mathematics), Geology, Astrobiology
Published
2021

36. Mars 2020 Mission Overview

Author

James F. Bell, Kevin P. Hand, Claire E. Newman, Mitch Schulte, Roger C. Wiens, Peter Willis, Y. S. Goreva, Robert C. Moeller, Adam Nelessen, Christopher D. K. Herd, Joel A. Hurowitz, Yang Liu, N. Spanovich, Justin N. Maki, Kathryn M. Stack, German Martinez, Kenneth A. Farley, Ricardo Hueso, Rohit Bhartia, Adrian J. Brown, Svein-Erik Hamran, Al Chen, Daniel Nunes, Adrian Ponce, David A. Paige, José Antonio Rodríguez-Manfredi, Luther W. Beegle, Sylvestre Maurice, Kenneth H. Williford, and Manuel de la Torre

Subjects
Martian, 010504 meteorology & atmospheric sciences, Astronomy and Astrophysics, Atmosphere of Mars, Mars Exploration Program, Exploration of Mars, Life on Mars, 01 natural sciences, Regolith, Astrobiology, Mars rover, Space and Planetary Science, Martian surface, 0103 physical sciences, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences
Abstract

The Mars 2020 mission will seek the signs of ancient life on Mars and will identify, prepare, document, and cache a set of samples for possible return to Earth by a follow-on mission. Mars 2020 and its Perseverance rover thus link and further two long-held goals in planetary science: a deep search for evidence of life in a habitable extraterrestrial environment, and the return of martian samples to Earth for analysis in terrestrial laboratories. The Mars 2020 spacecraft is based on the design of the highly successful Mars Science Laboratory and its Curiosity rover, but outfitted with a sophisticated suite of new science instruments. Ground-penetrating radar will illuminate geologic structures in the shallow subsurface, while a multi-faceted weather station will document martian environmental conditions. Several instruments can be used individually or in tandem to map the color, texture, chemistry, and mineralogy of rocks and regolith at the meter scale and at the submillimeter scale. The science instruments will be used to interpret the geology of the landing site, to identify habitable paleoenvironments, to seek ancient textural, elemental, mineralogical and organic biosignatures, and to locate and characterize the most promising samples for Earth return. Once selected, ∼35 samples of rock and regolith weighing about 15 grams each will be drilled directly into ultraclean and sterile sample tubes. Perseverance will also collect blank sample tubes to monitor the evolving rover contamination environment. In addition to its scientific instruments, Perseverance hosts technology demonstrations designed to facilitate future Mars exploration. These include a device to generate oxygen gas by electrolytic decomposition of atmospheric carbon dioxide, and a small helicopter to assess performance of a rotorcraft in the thin martian atmosphere. Mars 2020 entry, descent, and landing (EDL) will use the same approach that successfully delivered Curiosity to the martian surface, but with several new features that enable the spacecraft to land at previously inaccessible landing sites. A suite of cameras and a microphone will for the first time capture the sights and sounds of EDL. Mars 2020’s landing site was chosen to maximize scientific return of the mission for astrobiology and sample return. Several billion years ago Jezero crater held a 40 km diameter, few hundred-meter-deep lake, with both an inflow and an outflow channel. A prominent delta, fine-grained lacustrine sediments, and carbonate-bearing rocks offer attractive targets for habitability and for biosignature preservation potential. In addition, a possible volcanic unit in the crater and impact megabreccia in the crater rim, along with fluvially-deposited clasts derived from the large and lithologically diverse headwaters terrain, contribute substantially to the science value of the sample cache for investigations of the history of Mars and the Solar System. Even greater diversity, including very ancient aqueously altered rocks, is accessible in a notional rover traverse that ascends out of Jezero crater and explores the surrounding Nili Planum. Mars 2020 is conceived as the first element of a multi-mission Mars Sample Return campaign. After Mars 2020 has cached the samples, a follow-on mission consisting of a fetch rover and a rocket could retrieve and package them, and then launch the package into orbit. A third mission could capture the orbiting package and return it to Earth. To facilitate the sample handoff, Perseverance could deposit its collection of filled sample tubes in one or more locations, called depots, on the planet’s surface. Alternatively, if Perseverance remains functional, it could carry some or all the samples directly to the retrieval spacecraft. The Mars 2020 mission and its Perseverance rover launched from the Eastern Range at Cape Canaveral Air Force Station, Florida, on July 30, 2020. Landing at Jezero Crater will occur on Feb 18, 2021 at about 12:30 PM Pacific Time.

Published
2020

37. On the Habitability and Future Exploration of Ocean Worlds

Author

Athena Coustenis, Alexander G. Hayes, Kevin P. Hand, Christophe Sotin, Jet Propulsion Laboratory (JPL), NASA-California Institute of Technology (CALTECH), Cornell University [New York], Laboratoire d'études spatiales et d'instrumentation en astrophysique (LESIA (UMR_8109)), Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, and Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université de Paris (UP)

Subjects
Solar System, 010504 meteorology & atmospheric sciences, Liquid water, Habitability, Astronomy and Astrophysics, 01 natural sciences, Astrobiology, Lead (geology), Planetary science, Extant taxon, [SDU]Sciences of the Universe [physics], 13. Climate action, Space and Planetary Science, 0103 physical sciences, 14. Life underwater, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences
Abstract

International audience; Liquid water oceans are now predicted to exist beneath the icy shells of numerous worlds in the outer solar system. These ocean worlds are prime targets in our search for evidence of life beyond Earth, and specifically extant life. Here we review the conditions that may lead to several of these worlds being habitable, and provide a framework for the future exploration of these astrobiologically compelling targets.

Published
2020

38. Evidence for ammonia-bearing species on the Uranian satellite Ariel supports recent geologic activity

Author

Chloe B. Beddingfield, Francesca Scipioni, Joshua P. Emery, Dale P. Cruikshank, William M. Grundy, Kevin P. Hand, Tom Nordheim, Joe Roser, and Richard Cartwright

Subjects
Earth and Planetary Astrophysics (astro-ph.EP), Physics, Photon, Spectral signature, 010504 meteorology & atmospheric sciences, Uranus, FOS: Physical sciences, Magnetosphere, Astronomy and Astrophysics, Cosmic ray, Astrophysics, medicine.disease_cause, 01 natural sciences, Charged particle, Spectral line, Space and Planetary Science, 0103 physical sciences, medicine, 010303 astronomy & astrophysics, Ultraviolet, 0105 earth and related environmental sciences, Astrophysics - Earth and Planetary Astrophysics
Abstract

We investigated whether ammonia-rich constituents are present on the surface of the Uranian moon Ariel by analyzing 32 near-infrared reflectance spectra collected over a wide range of sub-observer longitudes and latitudes. We measured the band areas and depths of a 2.2-{\micron} feature in these spectra, which has been attributed to ammonia-bearing species on other icy bodies. Ten spectra display prominent 2.2-{\micron} features with band areas and depths > 2{\sigma}. We determined the longitudinal distribution of the 2.2-{\micron} band, finding no statistically meaningful differences between Ariel's leading and trailing hemispheres, indicating that this band is distributed across Ariel's surface. We compared the band centers and shapes of the five Ariel spectra displaying the strongest 2.2-{\micron} bands to laboratory spectra of various ammonia-bearing and ammonium-bearing species, finding that the spectral signatures of the Ariel spectra are best matched by ammonia-hydrates and flash frozen ammonia-water solutions. Our analysis also revealed that four Ariel spectra display 2.24-{\micron} bands (> 2{\sigma} band areas and depths), with band centers and shapes that are best matched by ammonia ice. Because ammonia should be efficiently removed over short timescales by ultraviolet photons, cosmic rays, and charged particles trapped in Uranus' magnetosphere, the possible presence of this constituent supports geologic activity in the recent past, such as emplacement of ammonia-rich cryolavas and exposure of ammonia-rich deposits by tectonism, impact events, and mass wasting.

Published
2020

39. Demonstration of Autonomous Nested Search for Local Maxima Using an Unmanned Underwater Vehicle

Author

James McMahon, Guangyu Xu, Christopher R. German, Michael V. Jakuba, Steve Chien, Kevin P. Hand, James C. Kinsey, Andrew D. Bowen, Jeffrey S. Seewald, and Andrew Branch

Subjects
0209 industrial biotechnology, Solar System, 010504 meteorology & atmospheric sciences, business.industry, 02 engineering and technology, 01 natural sciences, Hydrothermal circulation, Vehicle dynamics, Maxima and minima, 020901 industrial engineering & automation, Software deployment, Unmanned underwater vehicle, Aerospace engineering, business, Transit (satellite), Geology, 0105 earth and related environmental sciences, Hydrothermal vent
Abstract

Ocean Worlds represent one of the best chances for extra-terrestrial life in our solar system. A new mission concept must be developed to explore these oceans. This mission would require traversing the 10s of km thick icy shell and releasing a submersible into the ocean below. During the transit of the icy shell and the exploration of the ocean, the vehicle(s) would be out of contact with Earth for weeks or potentially months at a time. During this time the vehicle must have sufficient autonomy to locate and study scientific targets of interest. One such target of interest is hydrothermal venting. We have previously developed an autonomous nested search method to locate and investigate sources of hydrothermal venting by locating local maxima in hydrothermal vent emissions. In this work we demonstrate this approach on board an OceanServer Iver2 AUV in Chesapeake Bay, MD using simulated sensor data from a hydrothermal plume model. This represents the first step towards the deployment of this approach in conditions analogous to those that we might expect on an Ocean World.

Published
2020

41. Preservation of potential biosignatures in the shallow subsurface of Europa

Author

Kevin P. Hand, Chris Paranicas, and Tom Nordheim

Subjects
Radiation processing, 010504 meteorology & atmospheric sciences, Radiation dose, Lead (sea ice), Magnetosphere, Astronomy and Astrophysics, Crust, Radiation, 01 natural sciences, Latitude, Astrobiology, Jupiter, 0103 physical sciences, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences
Abstract

Jupiter’s moon Europa, which is thought to possess a large liquid water ocean beneath its icy crust, is one of the most compelling targets in the search for life beyond Earth. Its geologically young surface, along with a number of surface features, indicate that material from Europa’s interior may be emplaced on the surface. However, the surface is affected by the harsh radiation environment of Jupiter’s magnetosphere, which over time may lead to chemical alteration and destruction of potential biosignatures. We show that radiation dose rates are highly dependent on surface location. Radiation processing and destruction of potential biosignatures is found to be significant down to depths of ~1 cm in mid- to high-latitude regions, and to depths of 10–20 cm within ‘radiation lenses’ centred on the leading and trailing hemispheres. These results indicate that future missions to Europa’s surface do not need to excavate material to great depths to investigate the composition of endogenic material and search for potential biosignatures. A model reconstructs the radiation dose from both protons and electrons on Europa’s surface. Using laboratory data on irradiated amino acids, it shows that organics can be preserved at detectable levels at depths of just a few centimetres at mid-to-high latitudes and in young (

Published
2018

42. The Possible Emergence of Life and Differentiation of a Shallow Biosphere on Irradiated Icy Worlds: The Example of Europa

Author

Michael J. Russell, Alison E. Murray, and Kevin P. Hand

Subjects
Convection, Extraterrestrial Environment, 010504 meteorology & atmospheric sciences, Hydrogen, Oceans and Seas, Origin of Life, chemistry.chemical_element, 01 natural sciences, Hydrothermal circulation, Methane, Astrobiology, Hypothesis Articles, chemistry.chemical_compound, Exobiology, 0103 physical sciences, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Radiation, Ice, Biosphere, Carbon Dioxide, Agricultural and Biological Sciences (miscellaneous), chemistry, Space and Planetary Science, Jupiter, Extraterrestrial life, Carbon dioxide, Thermodynamics, Mafic, Metabolic Networks and Pathways
Abstract

Irradiated ice-covered ocean worlds with rocky mafic mantles may provide the conditions needed to drive the emergence and maintenance of life. Alkaline hydrothermal springs—relieving the geophysical, thermal, and chemical disequilibria between oceans and tidally stressed crusts—could generate inorganic barriers to the otherwise uncontrolled and kinetically disfavored oxidation of hydrothermal hydrogen and methane. Ionic gradients imposed across these inorganic barriers, comprising iron oxyhydroxides and sulfides, could drive the hydrogenation of carbon dioxide and the oxidation of methane through thermodynamically favorable metabolic pathways leading to early life-forms. In such chemostatic environments, fuels may eventually outweigh oxidants. Ice-covered oceans are primarily heated from below, creating convection that could transport putative microbial cells and cellular cooperatives upward to congregate beneath an ice shell, potentially giving rise to a highly focused shallow biosphere. It is here where electron acceptors, ultimately derived from the irradiated surface, could be delivered to such life-forms through exchange with the icy surface. Such zones would act as “electron disposal units” for the biosphere, and occupants might be transferred toward the surface by buoyant diapirs and even entrained into plumes. Key Words: Biofilms—Europa—Extraterrestrial life—Hydrothermal systems. Astrobiology 17, 1265–1273.

Published
2017

43. Spectral Behavior of Irradiated Sodium Chloride Crystals Under Europa‐Like Conditions

Author

Robert W. Carlson, Michael J. Poston, and Kevin P. Hand

Subjects
Materials science, 010504 meteorology & atmospheric sciences, Sodium, chemistry.chemical_element, 01 natural sciences, Geophysics, Planetary science, chemistry, Space and Planetary Science, Geochemistry and Petrology, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Irradiation, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Nuclear chemistry
Published
2017

44. A Comprehensive Revisit of Select Galileo/NIMS Observations of Europa

Author

Kevin P. Hand, Nikole K. Lewis, Robert W. Carlson, Jonathan I. Lunine, Ishan Mishra, Paul Helfenstein, and Ryan J. MacDonald

Subjects
Earth and Planetary Astrophysics (astro-ph.EP), Physics, Spectrometer, Near-infrared spectroscopy, FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics, Regolith, Spectral line, Amorphous solid, Wavelength, Geophysics, Space and Planetary Science, Earth and Planetary Sciences (miscellaneous), Porosity, Absorption (electromagnetic radiation), Astrophysics - Earth and Planetary Astrophysics
Abstract

The Galileo Near Infrared Mapping Spectrometer (NIMS) collected spectra of Europa in the 0.7-5.2 $\mu$m wavelength region, which have been critical to improving our understanding of the surface composition of this moon. However, most of the work done to get constraints on abundances of species like water ice, hydrated sulfuric acid, hydrated salts and oxides have used proxy methods, such as absorption strength of spectral features or fitting a linear mixture of laboratory generated spectra. Such techniques neglect the effect of parameters degenerate with the abundances, such as the average grain-size of particles, or the porosity of the regolith. In this work we revisit three Galileo NIMS spectra, collected from observations of the trailing hemisphere of Europa, and use a Bayesian inference framework, with the Hapke reflectance model, to reassess Europa's surface composition. Our framework has several quantitative improvements relative to prior analyses: (1) simultaneous inclusion of amorphous and crystalline water ice, sulfuric-acid-octahydrate (SAO), CO$_2$, and SO$_2$; (2) physical parameters like regolith porosity and radiation-induced band-center shift; and (3) tools to quantify confidence in the presence of each species included in the model, constrain their parameters, and explore solution degeneracies. We find that SAO strongly dominates the composition in the spectra considered in this study, while both forms of water ice are detected at varying confidence levels. We find no evidence of either CO$_2$ or SO$_2$ in any of the spectra; we further show through a theoretical analysis that it is highly unlikely that these species are detectable in any 1-2.5 $\mu$m Galileo NIMS data., Comment: 30 pages, 12 figures. Published in the Planetary Science Journal

Published
2021

45. Effect of H2S on the Near-infrared Spectrum of Irradiation Residue and Applications to the Kuiper Belt Object (486958) Arrokoth

Author

Michael E. Brown, Michael J. Poston, Robert Hodyss, Bethany L. Ehlmann, Jordana Blacksberg, Ahmed Mahjoub, John M. Eiler, Mathieu Choukroun, and Kevin P. Hand

Subjects
Physics, Residue (complex analysis), Space and Planetary Science, Near-infrared spectroscopy, Astronomy and Astrophysics, Irradiation, Astrophysics, Object (computer science), Spectrum (topology)
Published
2021

46. The near-surface electron radiation environment of Saturn's moon Mimas

Author

Amanda R. Hendrix, Kevin P. Hand, Geraint H. Jones, Tom Nordheim, Carly Howett, Andrew J. Coates, and Chris Paranicas

Subjects
Physics, Range (particle radiation), Guiding center, 010504 meteorology & atmospheric sciences, Spectrometer, Infrared, Astronomy, Astronomy and Astrophysics, 01 natural sciences, Charged particle, Interplanetary dust cloud, Space and Planetary Science, Saturn, Physics::Space Physics, 0103 physical sciences, Astrophysics::Earth and Planetary Astrophysics, Penetration depth, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences
Abstract

Saturn's inner mid-size moons are exposed to a number of external weathering processes, including charged particle bombardment and UV photolysis, as well as deposition of E-ring grains and interplanetary dust. While optical remote sensing observations by several instruments onboard the Cassini spacecraft have revealed a number of weathering patterns across the surfaces of these moons, it is not entirely clear which external process is responsible for which observed weathering pattern. Here we focus on Saturn's moon Mimas and model the effect of energetic electron bombardment across its surface. By using a combination of a guiding center, bounce-averaged charged particle tracing approach and a particle physics code, we investigate how the radiation dose due to energetic electrons is deposited with depth at different locations. We predict a lens-shaped electron energy deposition pattern that extends down to ∼cm depths at low latitudes centered around the apex of the leading hemisphere (90° W). These results are consistent with previous remote sensing observations of a lens-shaped color anomaly observed by the Imaging Science Subsystem (ISS) instrument as well as a thermal inertia anomaly observed by the Visual and Infrared Mapping Spectrometer (VIMS) and the Composite Infrared Spectrometer (CIRS). Our results confirm that these features are produced by MeV electrons that have a penetration depth into the surface comparable to the effective sampling depths of these instruments. On the trailing hemisphere we predict a similar lens-shaped electron energy deposition pattern, whose effects have to date not been observed by the Cassini remote sensing instruments. We suggest that no corresponding lens-shaped weathering pattern has been observed on the trailing hemisphere because of the comparatively short range of lower energy (

Published
2017

47. Follow the Oxygen: Comparative Histories of Planetary Oxygenation and Opportunities for Aerobic Life

Author

Kevin P. Hand, Vlada Stamenkovic, Lewis M. Ward, and Woodward W. Fischer

Subjects
010504 meteorology & atmospheric sciences, Extraterrestrial Environment, Cell Respiration, chemistry.chemical_element, Mars, Photosynthesis, 01 natural sciences, Oxygen, Astrobiology, Atmosphere, 0103 physical sciences, Exobiology, Ice Cover, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Abiotic component, Planetary habitability, Great Oxygenation Event, Temperature, Water, Mars Exploration Program, Photochemical Processes, Agricultural and Biological Sciences (miscellaneous), Abiogenic petroleum origin, chemistry, Space and Planetary Science, Jupiter, Evolution, Planetary, Oxidation-Reduction
Abstract

Aerobic respiration—the reduction of molecular oxygen (O_2) coupled to the oxidation of reduced compounds such as organic carbon, ferrous iron, reduced sulfur compounds, or molecular hydrogen while conserving energy to drive cellular processes—is the most widespread and bioenergetically favorable metabolism on Earth today. Aerobic respiration is essential for the development of complex multicellular life; thus the presence of abundant O_2 is an important metric for planetary habitability. O_2 on Earth is supplied by oxygenic photosynthesis, but it is becoming more widely understood that abiotic processes may supply meaningful amounts of O_2 on other worlds. The modern atmosphere and rock record of Mars suggest a history of relatively high O2 as a result of photochemical processes, potentially overlapping with the range of O_2 concentrations used by biology. Europa may have accumulated high O_2 concentrations in its subsurface ocean due to the radiolysis of water ice at its surface. Recent modeling efforts suggest that coexisting water and O2 may be common on exoplanets, with confirmation from measurements of exoplanet atmospheres potentially coming soon. In all these cases, O_2 accumulates through abiotic processes—independent of water-oxidizing photosynthesis. We hypothesize that abiogenic O_2 may enhance the habitability of some planetary environments, allowing highly energetic aerobic respiration and potentially even the development of complex multicellular life which depends on it, without the need to first evolve oxygenic photosynthesis. This hypothesis is testable with further exploration and life-detection efforts on O_2-rich worlds such as Mars and Europa, and comparison to O_2-poor worlds such as Enceladus. This hypothesis further suggests a new dimension to planetary habitability: “Follow the Oxygen,” in which environments with opportunities for energy-rich metabolisms such as aerobic respiration are preferentially targeted for investigation and life detection.

Published
2019

48. Sodium chloride on the surface of Europa

Author

Kevin P. Hand, Michael E. Brown, and Samantha K. Trumbo

Subjects
010504 meteorology & atmospheric sciences, Infrared, Astronomy, Sodium, chemistry.chemical_element, Astrophysics::Cosmology and Extragalactic Astrophysics, 01 natural sciences, Astrobiology, chemistry.chemical_compound, 0103 physical sciences, Physics::Atomic and Molecular Clusters, 14. Life underwater, Sulfate, 010303 astronomy & astrophysics, Chemical composition, Astrophysics::Galaxy Astrophysics, Research Articles, 0105 earth and related environmental sciences, Multidisciplinary, SciAdv r-articles, Sulfur, Planetary science, chemistry, 13. Climate action, Physics::Space Physics, Radiolysis, Astrophysics::Earth and Planetary Astrophysics, Chaos terrain, Planetary Science, Research Article
Abstract

Spectra from the Hubble Space Telescope show evidence for sodium chloride in material likely sourced from Europa’s interior., The potential habitability of Europa’s subsurface ocean depends on its chemical composition, which may be reflected in that of Europa’s geologically young surface. Investigations using Galileo Near-Infrared Mapping Spectrometer data led to the prevailing view that Europa’s endogenous units are rich in sulfate salts. However, recent ground-based infrared observations have suggested that, while regions experiencing sulfur radiolysis may contain sulfate salts, Europa’s more pristine endogenous material may reflect a chloride-dominated composition. Chlorides have no identifying spectral features at infrared wavelengths, but develop distinct visible-wavelength absorptions under irradiation, like that experienced on the surface of Europa. Using spectra obtained with the Hubble Space Telescope, we present the detection of a 450-nm absorption indicative of irradiated sodium chloride on the surface. The feature correlates with geologically disrupted chaos terrain, suggesting an interior source. The presence of endogenous sodium chloride on the surface of Europa has important implications for our understanding of its subsurface chemistry.

Published
2019

49. Differential Incorporation of Bacteria, Organic Matter, and Inorganic Ions Into Lake Ice During Ice Formation

Author

Trista J. Vick-Majors, Juliana D'Andrilli, Kevin P. Hand, John C. Priscu, Pamela A. Santibáñez, Amy Chiuchiolo, and Alexander B. Michaud

Subjects
chemistry.chemical_classification, Atmospheric Science, Ice formation, Ecology, biology, Paleontology, Soil Science, Forestry, Aquatic Science, Inorganic ions, biology.organism_classification, chemistry, Environmental chemistry, Environmental science, Lake ice, Organic matter, Bacteria, Water Science and Technology
Abstract

The segregation of bacteria, inorganic solutes, and total organic carbon between liquid water and ice during winter ice formation on lakes can significantly influence the concentration and survival of microorganisms in icy systems and their roles in biogeochemical processes. Our study quantifies the distributions of bacteria and solutes between liquid and solid water phases during progressive freezing. We simulated lake ice formation in mesocosm experiments using water from perennially (Antarctica) and seasonally (Alaska and Montana, United States) ice-covered lakes. We then computed concentration factors and effective segregation coefficients, which are parameters describing the incorporation of bacteria and solutes into ice. Experimental results revealed that, contrary to major ions, bacteria were readily incorporated into ice and did not concentrate in the liquid phase. The organic matter incorporated into the ice was labile, amino acid-like material, differing from the humic-like compounds that remained in the liquid phase. Results from a control mesocosm experiment (dead bacterial cells) indicated that viability of bacterial cells did not influence the incorporation of free bacterial cells into ice, but did have a role in the formation and incorporation of bacterial aggregates. Together, these findings demonstrate that bacteria, unlike other solutes, were preferentially incorporated into lake ice during our freezing experiments, a process controlled mainly by the initial solute concentration of the liquid water source, regardless of cell viability.

Published
2019

50. H$_2$O$_2$ within chaos terrain on Europa's leading hemisphere

Author

Kevin P. Hand, Michael E. Brown, and Samantha K. Trumbo

Subjects
Physics, Earth and Planetary Astrophysics (astro-ph.EP), 010504 meteorology & atmospheric sciences, FOS: Physical sciences, Astronomy and Astrophysics, Geophysics, 01 natural sciences, 13. Climate action, Space and Planetary Science, 0103 physical sciences, Chaos terrain, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Astrophysics - Earth and Planetary Astrophysics
Abstract

Hydrogen peroxide is part of an important radiolytic cycle on Europa and may be a critical source of oxidants to the putative subsurface ocean. The surface geographic distribution of hydrogen peroxide may constrain the processes governing its abundance as well as its potential relevance to the subsurface chemistry. However, maps of Europa's hydrogen peroxide beyond hemispherical averages have never been published. Here, we present spatially resolved L-band (3.16 - 4 $\mu$m) observations of Europa's 3.5 $\mu$m hydrogen peroxide absorption, which we obtained using the near-infrared spectrometer NIRSPEC and the adaptive optics system on the Keck II telescope. Using these data, we map the strength of the 3.5 $\mu$m absorption across the surface at a nominal spatial resolution of $\sim$300 km. Though previous disk-integrated data seemed consistent with the laboratory expectation that Europa's hydrogen peroxide exists primarily in its coldest and iciest regions, we find nearly the exact opposite at this finer spatial scale. Instead, we observe the largest hydrogen peroxide absorptions at low latitudes on the leading and anti-Jovian hemispheres, correlated with chaos terrain, and relative depletions toward the cold, icy high latitudes. This distribution may reflect the effects of decreased hydrogen peroxide destruction due to efficient electron scavenging by CO$_2$ within chaos terrain., Comment: 7 pages, 2 figures, accepted for publication in the Astronomical Journal

Published
2019
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