Your search keyword '"Alfonso F. Davila"' showing total 27 results

1. Returning Samples From Enceladus for Life Detection

Author

Marc Neveu, Ariel D. Anbar, Alfonso F. Davila, Daniel P. Glavin, Shannon M. MacKenzie, Charity M. Phillips-Lander, Brent Sherwood, Yoshinori Takano, Peter Williams, and Hajime Yano

Subjects

Enceladus, astrobiology, sample return, life detection, ocean worlds, icy satellites, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809

Abstract

Evidence suggests that Saturn's icy moon Enceladus has a subsurface ocean that sources plumes of water vapor and ice vented to space from its south pole. In situ analyses of this material by the Cassini spacecraft have shown that the ocean contains key ingredients for life (elements H, C, N, O and possibly S; simple and complex organic compounds; chemical disequilibria at water-rock interfaces; clement temperature, pressure, and pH). The Cassini discoveries make Enceladus' interior a prime locale for life detection beyond Earth. Scant material exchange with the inner Solar System makes it likely that such life would have emerged independently of life on Earth. Thus, its discovery would illuminate life's universal characteristics. The alternative result of an upper bound on a detectable biosphere in an otherwise habitable environment would likewise considerably advance our understanding of the prevalence of life beyond Earth. Here we outline the rationale for returning vented ocean samples, accessible from Enceladus' surface or low altitudes, to Earth for life detection. Returning samples allows analyses using laboratory instruments that cannot be flown, with decades or more to adapt and repeat analyses. We describe an example set of measurements to estimate the amount of sample to be returned and discuss possible mission architectures and collection approaches. We then turn to the challenges of preserving sample integrity and implementing planetary protection policy. We conclude by placing such a mission in the broader context of Solar System exploration.

Published

2020

2. Adaptations of Endolithic Communities to Abrupt Environmental Changes in A Hyper-Arid Desert

Author

Cesar Perez-Fernandez, Paul Wilburn, Alfonso F Davila, and Jocelyne DiRuggiero

Subjects

Exobiology

Abstract

The adaptation mechanisms of microbial communities to natural perturbations remain relatively unexplored, particularly in extreme environments. The extremophilic communities of halite (NaCl) nodules from the hyper-arid core of the Atacama Desert are self-sustained and represent a unique opportunity to study functional adaptations and community dynamics with changing environmental conditions. We transplanted halite nodules to different sites in the desert and investigated how their taxonomic, cellular, and biochemical changes correlated with water availability, using environmental data modeling and metagenomic analyses. Salt-in strategists, mainly represented by haloarchaea, significantly increased in relative abundance at sites characterized by extreme dryness, multiple wet/dry cycles, and colder conditions. The functional analysis of metagenome-assembled genomes (MAGs) revealed site-specific enrichments in archaeal MAGs encoding for the uptake of various compatible solutes and for glycerol utilization. These findings suggest that opportunistic salt-in strategists took over the halite communities at the driest sites. They most likely benefited from metabolites newly released in the environment by the death of microorganisms least adapted to the new conditions. The observed changes were consistent with the need to maximize cellular bioenergetics when confronted with lower water availability and higher salinity, providing valuable information on microbial community adaptations and resilience to climate change.

Published

2022

3. Planetary protection assessment of radioisotope thermoelectric generator (RTG)-powered landed missions to ocean worlds: application to Enceladus

Author

Marc Neveu, Robert F. Coker, Ralph D. Lorenz, Shannon M. MacKenzie, Jonathan I. Lunine, and Alfonso F. Davila

Subjects

Earth Resources And Remote Sensing

Abstract

Landed missions to icy worlds with a subsurface liquid water ocean must meet planetary protection requirements, and ensure a sufficiently small likelihood of any microorganism-bearing part of the landed element reaching the ocean. A higher bound on this likelihood is set by the potential for radioisotope thermoelectric generator (RTG) power sources, the hottest possible landed element, to melt through the ice shell and reach the ocean. Here, we quantify this potential as a function of three key parameters: surface temperature, ice shell thickness (i.e., heat flux through the shell), and thickness of a porous (insulating) snow or regolith cover. Although the model we describe can be applied to any ocean world, we present results in the context of a landed mission concept to the south polar terrain of Saturn’s moon Enceladus. In this particular context, we discuss planetary protection considerations for landing site selection. The likelihood of forward microbial contamination of Enceladus’ ocean by an RTG-powered landed mission can be made sufficiently low to not undermine compliance with planetary protection policy.

Published

2022

4. Science Objectives for Flagship-Class Mission Concepts for the Search for Evidence of Life at Enceladus

Author

Shannon M. MacKenzie, Marc Neveu, Alfonso F. Davila, Jonathan I. Lunine, Morgan L. Cable, Charity M. Phillips-Lander, Jennifer L. Eigenbrode, J. Hunter Waite, Kate L. Craft, Jason D. Hofgartner, Chris P. McKay, Christopher R. Glein, Dana Burton, Samuel P. Kounaves, Richard A. Mathies, Steven D. Vance, Michael J. Malaska, Robert Gold, Christopher R. German, Krista M. Soderlund, Peter Willis, Caroline Freissinet, Alfred S. McEwen, John Robert Brucato, Jean-Pierre P. de Vera, Tori M. Hoehler, and Jennifer Heldmann

Subjects

Exobiology

Abstract

Cassini revealed that Saturn's Moon Enceladus hosts a subsurface ocean that meets the accepted criteria for habitability with bio-essential elements and compounds, liquid water, and energy sources available in the environment. Whether these conditions are sufficiently abundant and collocated to support life remains unknown and cannot be determined from Cassini data. However, thanks to the plume of oceanic material emanating from Enceladus’ south pole, a new mission to Enceladus could search for evidence of life without having to descend through kilometers of ice. In this article, we outline the science motivations for such a successor to Cassini, choosing the primary science goal to be determining whether Enceladus is inhabited and assuming a resource level equivalent to NASA's Flagship-class missions. We selected a set of potential biosignature measurements that are complementary and orthogonal to build a robust case for any life detection result. This result would be further informed by quantifications of the habitability of the environment through geochemical and geophysical investigations into the ocean and ice shell crust. This study demonstrates that Enceladus’ plume offers an unparalleled opportunity for in situ exploration of an Ocean World and that the planetary science and astrobiology community is well equipped to take full advantage of it in the coming decades.

Published

2022

5. The Enceladus Orbilander Mission Concept: Balancing Return and Resources in the Search for Life

Author

Shannon M. MacKenzie, Marc Neveu, Alfonso F Davila, Jonathan I Lunine, Kathleen L Craft, Morgan L Cable, Charity M Phillips-Lander, Jason D Hofgartner, Jennifer L Eigenbrode, J Hunter Waite, Jr, Christopher R Glein, Robert Gold, Peter J Greenauer, Karen Kirby, Christopher Bradburne, Samuel P Kounaves, Michael J Malaska, Frank Postberg, G Wesley Patterson, Carolyn Porco, Jorge I Nunez, Chris German, Julie A Huber, Christopher P Mckay, Jean-Pierre de Vera, John Robert Brucato, and Linda Joyce Spilker

Subjects

Lunar And Planetary Science And Exploration

Abstract

Enceladus’s long-lived plume of ice grains and water vapor makes accessing oceanic material readily achievable from orbit (around Saturn or Enceladus) and from the moon’s surface. In preparation for the National Academies of Sciences, Engineering and Medicine 2023–2032 Planetary Science and Astrobiology Decadal Survey, we investigated four architectures capable of collecting and analyzing plume material from orbit and/or on the surface to address the most pressing questions at Enceladus: Is the subsurface ocean inhabited? Why, or why not? Trades specific to these four architectures were studied to allow an evaluation of the science return with respect to investment. The team found that Orbilander, a mission concept that would first orbit and then land on Enceladus, represented the best balance. Orbilander was thus studied at a higher fidelity, including a more detailed science operations plan during both orbital and landed phases, landing site characterization and selection analyses, and landing procedures. The Orbilander mission concept demonstrates that scientifically compelling but resource-conscious Flagship-class missions can be executed in the next decade to search for life at Enceladus.

Published

2021

6. Xeropreservation of Functionalized Lipid Biomarkers in Hyperarid Soils in the Atacama Desert

Author

Mary Beth Wilhelm, Alfonso F Davila, Jennifer L Eigenbrode, Mary N Parenteau, Linda L Jahnke, Xiao-Lei Liu, Roger E Summons, James J Wray, Brian N Stamos, Shane S O'Reilly, and Amy Williams

Subjects

Earth Resources And Remote Sensing, Life Sciences (General)

Abstract

Our understanding of long-term organic matter preservation comes mostly from studies in aquatic systems. In contrast, taphonomic processes in extremely dry environments are relatively understudied and are poorly understood. We investigated the accumulation and preservation of lipid biomarkers in hyperarid soils in the Yungay region of the Atacama Desert. Lipids from seven soil horizons in a 2.5 meter vertical profile were extracted and analyzed using GC-MS ( Gas Chromatography-Mass Spectrometry) and LC-MS (Liquid Chromatography-Mass Spectrometry). Diagnostic functionalized lipids and geolipids were detected and increased in abundance and diversity with depth. Deeper clay units contain fossil organic matter (radiocarbon dead) that has been protected from rainwater since the onset of hyperaridity. We show that these clay units contain lipids in an excellent state of structural preservation with functional groups and unsaturated bonds in carbon chains. This indicates that minimal degradation of lipids has occurred in these soils since the time of their deposition between more than 40,000 and up to 2 million years ago. The exceptional structural preservation of biomarkers is likely due to the long-term hyperaridity that has minimized microbial and enzymatic activity, a taphonomic process we term xeropreservation (i.e. preservation by drying). The degree of biomarker preservation allowed us to reconstruct major changes in ecology in the Yungay region that reflect a shift in hydrological regime from wet to dry since the early Quaternary. Our results suggest that hyperarid environments, which comprise 7.5 percent of the continental landmass, could represent a rich and relatively unexplored source of paleobiological information on Earth.

Published

2016

7. Habitability Models for Astrobiology

Author

Alfonso F. Davila, Juan F. Salazar, Guillermo Nery, Jorge I. Zuluaga, Nicole J. Torres-Santiago, Abel Méndez, E. Nathan, Edgard G. Rivera-Valentín, Frances Rivera-Hernandez, Marta Filipa Simões, Ramses M. Ramirez, Noam R. Izenberg, Grizelle González, Corine Brown, Justin Filiberto, Jesús Martínez-Frías, Howard Chen, Marcos Jusino-Maldonado, André Antunes, Dirk Schulze-Makuch, Ludmila Carone, Jacob Haqq-Misra, Tana E. Wood, Kevin N. Ortiz Ceballos, Madhu Kashyap Jagadeesh, René Heller, Dimitra Atri, Paul K. Byrne, Christopher P. McKay, Priscilla Nowajewski-Barra, Humberto Itic Carvajal Chitty, David C. Catling, Kennda Lynch, and Michael Malaska

Subjects

010504 meteorology & atmospheric sciences, Gradual transition, Extraterrestrial Environment, Earth, Planet, FOS: Physical sciences, Planets, 01 natural sciences, Quantitative Biology - Quantitative Methods, Astrobiology, 0103 physical sciences, Exobiology, Instrumentation and Methods for Astrophysics (astro-ph.IM), 010303 astronomy & astrophysics, Quantitative Methods (q-bio.QM), 0105 earth and related environmental sciences, Earth and Planetary Astrophysics (astro-ph.EP), Planetary habitability, Habitability, Agricultural and Biological Sciences (miscellaneous), Exoplanet, Habitat suitability, Key factors, Space and Planetary Science, FOS: Biological sciences, Environmental science, Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Earth and Planetary Astrophysics

Abstract

Habitability has been generally defined as the capability of an environment to support life. Ecologists have been using Habitat Suitability Models (HSMs) for more than four decades to study the habitability of Earth from local to global scales. Astrobiologists have been proposing different habitability models for some time, with little integration and consistency among them, being different in function to those used by ecologists. Habitability models are not only used to determine if environments are habitable or not, but they also are used to characterize what key factors are responsible for the gradual transition from low to high habitability states. Here we review and compare some of the different models used by ecologists and astrobiologists and suggest how they could be integrated into new habitability standards. Such standards will help to improve the comparison and characterization of potentially habitable environments, prioritize target selections, and study correlations between habitability and biosignatures. Habitability models are the foundation of planetary habitability science and the synergy between ecologists and astrobiologists is necessary to expand our understanding of the habitability of Earth, the Solar System, and extrasolar planets., Published in Astrobiology, 21(8). arXiv admin note: substantial text overlap with arXiv:2007.05491

Published

2021

8. Astrobiology of life on Earth

Author

Kathleen C. Benison, Hitesh Changela, Tiffany D. Dallas, Catharine A. Conley, Alfonso F. Davila, Rocco L. Mancinelli, Michael T. Madigan, John E. Hallsworth, Teresa Rinaldi, Ricardo Amils, Michail M. Yakimov, Alexander Rapoport, Laura Selbmann, Barbara Cavalazzi, Frances Westall, UAM. Departamento de Biología Molecular, Institute for Global Food Security [Belfast], Queen's University [Belfast] (QUB), Bay Area Environmental Research Institute (BAER), NASA Ames Research Center (ARC), Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome], Department of Geology and Geography [Morgantown], West Virginia University [Morgantown], University of Latvia (LU), University of Bologna, Università degli studi della Tuscia [Viterbo], Institute of Geology and Geophysics [Beijing] (IGG), Chinese Academy of Sciences [Beijing] (CAS), The University of New Mexico [Albuquerque], Centre de biophysique moléculaire (CBM), Université d'Orléans (UO)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC), Institute for Biological Resources and Marine Biotechnology (IRBIM), Universidad Autonoma de Madrid (UAM), Centro de Astrobiologia [Madrid] (CAB), Instituto Nacional de Técnica Aeroespacial (INTA)-Consejo Superior de Investigaciones Científicas [Madrid] (CSIC), Southern Illinois University [Carbondale] (SIU), Hallsworth J.E., Mancinelli R.L., Conley C.A., Dallas T.D., Rinaldi T., Davila A.F., Benison K.C., Rapoport A., Cavalazzi B., Selbmann L., Changela H., Westall F., Yakimov M.M., Amils R., Madigan M.T., Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome] (UNIROMA), University of Bologna/Università di Bologna, Université d'Orléans (UO)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), Universidad Autónoma de Madrid (UAM), Frapart, Isabelle, Hallsworth, J. E. [0000-0001-6797-9362], Mancinelli, R. L. [0000-0002-8200-4878], Dallas, T. D. [0000-0002-5310-9857], Rinaldi, T. [0000-0001-6291-245X], Benison, K. C. [0000-0001-6104-2333], Rapoport, A. [0000-0002-6185-0039], Selbmann, L. [0000-0002-8967-3329], Amils, R. [0000-0002-7560-1033], and Biotechnology and Biological Sciences Research Council (BBSRC)

Subjects

Extraterrestrial Environment, Earth, Planet, terrestrial life, Biology, Microbiology, Astrobiology, [SDU] Sciences of the Universe [physics], 03 medical and health sciences, Microbial ecology, halophiles, Exobiology, Environmental Microbiology, Extremophile, Humans, SDG 14 - Life Below Water, Ecology, Evolution, Behavior and Systematics, Ecosystem, extremophiles, 030304 developmental biology, 2. Zero hunger, 0303 health sciences, Extremophile Viruses, 030306 microbiology, Biosphere, Mars Exploration Program, 15. Life on land, Mars exploration, Biología y Biomedicina / Biología, habitability, Habitat, 13. Climate action, [SDU]Sciences of the Universe [physics], planetary protection, Earth (chemistry), astrobiology, extremophile, halophile

Abstract

Astrobiology is mistakenly regarded by some as a field confined to studies of life beyond Earth. Here, we consider life on Earth through an astrobiological lens. Whereas classical studies of microbiology historically focused on various anthropocentric sub-fields (such as fermented foods or commensals and pathogens of crop plants, livestock and humans), addressing key biological questions via astrobiological approaches can further our understanding of all life on Earth. We highlight potential implications of this approach through the articles in this Environmental Microbiology special issue ‘Ecophysiology of Extremophiles’. They report on the microbiology of places/processes including low-temperature environments and chemically diverse saline- and hypersaline habitats; aspects of sulphur metabolism in hypersaline lakes, dysoxic marine waters, and thermal acidic springs; biology of extremophile viruses; the survival of terrestrial extremophiles on the surface of Mars; biological soils crusts and rock-associated microbes of deserts; subsurface and deep biosphere, including a salticle formed within Triassic halite; and interactions of microbes with igneous and sedimentary rocks. These studies, some of which we highlight here, contribute to our understanding of the spatiotemporal reach of Earth'sfunctional biosphere, and the tenacity of terrestrial life. Their findings will help set the stage for future work focused on the constraints for life, and how organisms adapt and evolve to circumvent these constraints. Funding was provided by the Biotechnology and Biological Sciences Research Council (BBSRC, United Kingdom) project BBF003471. Peerreview

Published

2021

9. The Enceladus Orbilander Mission Concept: Balancing Return and Resources in the Search for Life

Author

Samuel P. Kounaves, Christopher R. Glein, Christopher E. Bradburne, Marc Neveu, Morgan L. Cable, Jorge I. Nunez, Chris German, Jean Pierre Paul de Vera, Christopher P. McKay, G. Wesley Patterson, Alfonso F. Davila, Jennifer L. Eigenbrode, John Robert Brucato, Michael Malaska, C. C. Porco, Julie A. Huber, Robert E. Gold, Jason D. Hofgartner, Frank Postberg, Peter J. Greenauer, Linder J. Spilker, Johnathan I. Lunine, J. Hunter Waite, Karen Kirby, Shannon MacKenzie, Charity M. Phillips-Lander, and Kathleen L. Craft

Subjects

010504 meteorology & atmospheric sciences, Planetare Labore, Astronomy and Astrophysics, 01 natural sciences, Astrobiology, Geophysics, Planetary science, Enceladus Orbilander Mission Concept, 13. Climate action, Space and Planetary Science, Saturn, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Orbit (dynamics), Enceladus, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

Enceladus’s long-lived plume of ice grains and water vapor makes accessing oceanic material readily achievable from orbit (around Saturn or Enceladus) and from the moon’s surface. In preparation for the National Academies of Sciences, Engineering and Medicine 2023–2032 Planetary Science and Astrobiology Decadal Survey, we investigated four architectures capable of collecting and analyzing plume material from orbit and/or on the surface to address the most pressing questions at Enceladus: Is the subsurface ocean inhabited? Why, or why not? Trades specific to these four architectures were studied to allow an evaluation of the science return with respect to investment. The team found that Orbilander, a mission concept that would first orbit and then land on Enceladus, represented the best balance. Orbilander was thus studied at a higher fidelity, including a more detailed science operations plan during both orbital and landed phases, landing site characterization and selection analyses, and landing procedures. The Orbilander mission concept demonstrates that scientifically compelling but resource-conscious Flagship-class missions can be executed in the next decade to search for life at Enceladus.

Published

2021

10. Effects of Gamma and Electron Radiation on the Structural Integrity of Organic Molecules and Macromolecular Biomarkers Measured by Microarray Immunoassays and Their Astrobiological Implications

Author

Graciela de Diego-Castilla, Erika Cavalcante-Silva, Alfonso F. Davila, Christopher P. McKay, Yolanda Blanco, Daniel Viúdez-Moreiras, José Antonio Rodríguez-Manfredi, and Victor Parro

Subjects

010504 meteorology & atmospheric sciences, Antibody microarray, Extraterrestrial Environment, Astrophysics::High Energy Astrophysical Phenomena, Cosmic ray, Electrons, Astrophysics::Cosmology and Extragalactic Astrophysics, 01 natural sciences, Organic molecules, Ionizing radiation, Astrobiology, Electron radiation, Molecular biomarker, Biopolymers, Planetary exploration, 0103 physical sciences, Exobiology, Astrophysics::Solar and Stellar Astrophysics, 010303 astronomy & astrophysics, Research Articles, 0105 earth and related environmental sciences, Immunoassay, Solar energetic particles, Molecular Structure, Chemistry, Structural integrity, Dose-Response Relationship, Radiation, Microarray Analysis, Agricultural and Biological Sciences (miscellaneous), Space and Planetary Science, Gamma radiation, Gamma Rays, Physics::Space Physics, Epitope, Astrophysics::Earth and Planetary Astrophysics, Haptens, Biomarkers, Cosmic Radiation, Macromolecule, Immunoidentification

Abstract

High-energy ionizing radiation in the form of solar energetic particles and galactic cosmic rays is pervasive on the surface of planetary bodies with thin atmospheres or in space facilities for humans, and it may seriously affect the chemistry and the structure of organic and biological material. We used fluorescent microarray immunoassays to assess how different doses of electron and gamma radiations affect the stability of target compounds such as biological polymers and small molecules (haptens) conjugated to large proteins. The radiation effect was monitored by measuring the loss in the immunoidentification of the target due to an impaired ability of the antibodies for binding their corresponding irradiated and damaged epitopes (the part of the target molecule to which antibodies bind). Exposure to electron radiation alone was more damaging at low doses (1 kGy) than exposure to gamma radiation alone, but this effect was reversed at the highest radiation dose (500 kGy). Differences in the dose–effect immunoidentification patterns suggested that the amount (dose) and not the type of radiation was the main factor for the cumulative damage on the majority of the assayed molecules. Molecules irradiated with both types of radiation showed a response similar to that of the individual treatments at increasing radiation doses, although the pattern obtained with electrons only was the most similar. The calculated radiolysis constant did not show a unique pattern; it rather suggested a different behavior perhaps associated with the unique structure of each molecule. Although not strictly comparable with extraterrestrial conditions because the irradiations were performed under air and at room temperature, our results may contribute to understanding the effects of ionizing radiation on complex molecules and the search for biomarkers through bioaffinity-based systems in planetary exploration.

Published

2018

11. Identification of chlorobenzene in the Viking gas chromatograph-mass spectrometer data sets: Reanalysis of Viking mission data consistent with aromatic organic compounds on Mars

Author

Melissa Guzman, Christopher P. McKay, Richard C. Quinn, Rafael Navarro-González, Cyril Szopa, Alfonso F. Davila, Caroline Freissinet, 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), NASA Ames Research Center (ARC), Laboratorio de Química de Plasmas y Estudios Planetarios [Mexico], Instituto de Ciencias Nucleares [Mexico], and Universidad Nacional Autónoma de México (UNAM)-Universidad Nacional Autónoma de México (UNAM)

Subjects

Martian, 010504 meteorology & atmospheric sciences, Spectrometer, [SDU.ASTR]Sciences of the Universe [physics]/Astrophysics [astro-ph], chemistry.chemical_element, Mars Exploration Program, 01 natural sciences, Astrobiology, chemistry.chemical_compound, Geophysics, chemistry, 13. Climate action, Space and Planetary Science, Geochemistry and Petrology, Chlorobenzene, 0103 physical sciences, Sample Analysis at Mars, Earth and Planetary Sciences (miscellaneous), Environmental science, Gas chromatography–mass spectrometry, 010303 astronomy & astrophysics, Pyrolysis, Carbon, 0105 earth and related environmental sciences

Abstract

International audience; Motivated by the recent detection of chlorobenzene by the Sample Analysis at Mars instrument suite on the Curiosity rover, and the identification of its carbon source as indigenous to the martian sample, we reexamined the original, microfilm preserved, Viking gas chromatograph‐mass spectrometer (GCMS) data sets. We found evidence for the presence of chlorobenzene in Viking Lander 2 (VL‐2) data at levels corresponding to 0.08‐1.0 ppb (relative to sample mass), in runs when the sample was heated to 350°C and 500°C. Additionally, we found a correlation between the temperature dependence of the chlorobenzene signal and the dichloromethane signal originally identified by the Viking GCMS team. We considered possible sources of carbon that may have produced the chlorobenzene signal, by reaction with perchlorate during pyrolysis, including organic carbon indigenous to the martian parent sample and instrument contamination. We conclude that the chlorobenzene signal measured by VL‐2 originated from martian chlorine sources. We show how the carbon source could originate from the martian parent sample, though a carbon source contributed from instrument background cannot yet be ruled out.

Published

2018

12. Xeropreservation of functionalized lipid biomarkers in hyperarid soils in the Atacama Desert

Author

M. N. Parenteau, Mary Beth Wilhelm, Rogers E. Summons, Shane S. O'Reilly, Jennifer L. Eigenbrode, Alfonso F. Davila, Linda L. Jahnke, Brian N. Stamos, Amy J. Williams, James J. Wray, and Xiao-Lei Liu

Subjects

chemistry.chemical_classification, Taphonomy, 010504 meteorology & atmospheric sciences, Ecology, Aquatic ecosystem, 010502 geochemistry & geophysics, 01 natural sciences, Article, law.invention, Deposition (aerosol physics), chemistry, Geochemistry and Petrology, law, Environmental chemistry, Soil water, Soil horizon, Organic matter, Radiocarbon dating, Quaternary, Geology, 0105 earth and related environmental sciences

Abstract

Our understanding of long-term organic matter preservation comes mostly from studies in aquatic systems. In contrast, taphonomic processes in extremely dry environments are relatively understudied and are poorly understood. We investigated the accumulation and preservation of lipid biomarkers in hyperarid soils in the Yungay region of the Atacama Desert. Lipids from seven soil horizons in a 2.5 m vertical profile were extracted and analyzed using GC-MS and LC-MS. Diagnostic functionalized lipids and geolipids were detected and increased in abundance and diversity with depth. Deeper clay units contain fossil organic matter (radiocarbon dead) that has been protected from rainwater since the onset of hyperaridity. We show that these clay units contain lipids in an excellent state of structural preservation with functional groups and unsaturated bonds in carbon chains. This indicates that minimal degradation of lipids has occurred in these soils since the time of their deposition between >40,000 and 2 million years ago. The exceptional structural preservation of biomarkers is likely due to the long-term hyperaridity that has minimized microbial and enzymatic activity, a taphonomic process we term xeropreservation (i.e. preservation by drying). The degree of biomarker preservation allowed us to reconstruct major changes in ecology in the Yungay region that reflect a shift in hydrological regime from wet to dry since the early Quaternary. Our results suggest that hyperarid environments, which comprise 7.5% of the continental landmass, could represent a rich and relatively unexplored source of paleobiological information on Earth.

Published

2016

13. Adaptation strategies of endolithic chlorophototrophs to survive the hyperarid and extreme solar radiation environment of the Atacama Desert

Author

Jacek eWierzchos, Jocelyne eDiRuggiero, Petr eVítek, Octavio eArtieda, Virginia eSouza-Egipsy, Pavel eSkaloud, Michael eTisza, Alfonso F Davila, Carlos eVílchez, Inés eGarbayo, Carmen eAscaso, Ministerio de Economía y Competitividad (España), National Science Foundation (US), Czech Science Foundation, and NASA Astrobiology Institute (US)

Subjects

Microbiology (medical), Cyanobacteria, lcsh:QR1-502, Ecological succession, Scytonemin, endolithic chlorophototrophs, Endolithic chlorophototrophs, Biology, Microbiology, lcsh:Microbiology, 03 medical and health sciences, chemistry.chemical_compound, Algae, Extreme environment, Colonization, extreme environment, 030304 developmental biology, Original Research, Atacama Desert, 2. Zero hunger, 0303 health sciences, 030306 microbiology, Ecology, carotenoids, Gypsum, 15. Life on land, biology.organism_classification, Carotenoids, gypsum, chemistry, Habitat, 13. Climate action, scytonemin, Adaptation

Abstract

The Atacama Desert, northern Chile, is one of the driest deserts on Earth and, as such, a natural laboratory to explore the limits of life and the strategies evolved by microorganisms to adapt to extreme environments. Here we report the exceptional adaptation strategies of chlorophototrophic and eukaryotic algae, and chlorophototrophic and prokaryotic cyanobacteria to the hyperarid and extremely high solar radiation conditions occurring in this desert. Our approach combined several microscopy techniques, spectroscopic analytical methods, and molecular analyses. We found that the major adaptation strategy was to avoid the extreme environmental conditions by colonizing cryptoendolithic, as well as, hypoendolithic habitats within gypsum deposits. The cryptoendolithic colonization occurred a few millimeters beneath the gypsum surface and showed a succession of organized horizons of algae and cyanobacteria, which has never been reported for endolithic microbial communities. The presence of cyanobacteria beneath the algal layer, in close contact with sepiolite inclusions, and their hypoendolithic colonization suggest that occasional liquid water might persist within these sub-microhabitats. We also identified the presence of abundant carotenoids in the upper cryptoendolithic algal habitat and scytonemin in the cyanobacteria hypoendolithic habitat. This study illustrates that successful lithobiontic microbial colonization at the limit for microbial life is the result of a combination of adaptive strategies to avoid excess solar irradiance and extreme evapotranspiration rates, taking advantage of the complex structural and mineralogical characteristics of gypsum deposits—conceptually called “rock's habitable architecture.” Additionally, self-protection by synthesis and accumulation of secondary metabolites likely produces a shielding effect that prevents photoinhibition and lethal photooxidative damage to the chlorophototrophs, representing another level of adaptation., CA, JD, OA, AD, and JW are thankful for financial support by CGL2013-42509P grant from MINECO, Spain. JD acknowledges funding from the NASA Exobiology Program (Grant EXOB08–0033) and from the National Science Foundation (Grant NSF-0918907), PV acknowledges funding from the Czech Science Foundation, project no. P210/12/P330 and ENVIMET project CZ.1.07/2.3.00/20.0246 and AD acknowledges funding from the NASA Exobiology Program (Grant NNX12AD61G) and the NASA Astrobiology Institute (NAI Grant NNX15BB01A to the SETI Institute).

Published

2015

14. Tracking the weathering of basalts on Mars using lithium isotope fractionation models

Author

Carolina Gil-Lozano, Christopher P. McKay, Alfonso F. Davila, Alberto G. Fairén, E. Losa-Adams, J. Alexis P. Rodriguez, L. Gago-Duport, Steven W. Squyres, Esther R. Uceda, and UAM. Departamento de Biología Molecular

Subjects

Atmospheres, 010504 meteorology & atmospheric sciences, Geochemistry, Volcanology, chemistry.chemical_element, Mars, Weathering, Fractionation, Lithium, 010502 geochemistry & geophysics, 01 natural sciences, Planetary Geochemistry, Planetary Sciences: Solar System Objects, Isotope fractionation, Geochemistry and Petrology, Planetary Sciences: Astrobiology, Isotopic fractionation, Planetary Sciences: Solid Surface Planets, Planetary Sciences: Fluid Planets, Research Articles, Mineralogy and Petrology, 0105 earth and related environmental sciences, Basalt, Stable isotope ratio, Hydrothermal Systems and Weathering on Other Planets, Basalt weathering, Composition of the Planets, Mass-independent fractionation, Biología y Biomedicina / Biología, Equilibrium fractionation, Geophysics, chemistry, 13. Climate action, Planetary Sciences: Comets and Small Bodies, Geochemical Modeling, Geology, Composition, Research Article

Abstract

An edited version of this paper was published by AGU. Copyright (2015) American Geophysical Union, Lithium (Li), the lightest of the alkali elements, has geochemical properties that include high aqueous solubility (Li is the most fluid mobile element) and high relative abundance in basalt-forming minerals (values ranking between 0.2 and 12 ppm). Li isotopes are particularly subject to fractionation because the two stable isotopes of lithium - 7Li and 6Li - have a large relative mass difference (∼15%) that results in significant fractionation between water and solid phases. The extent of Li isotope fractionation during aqueous alteration of basalt depends on the dissolution rate of primary minerals - the source of Li - and on the precipitation kinetics, leading to formation of secondary phases. Consequently, a detailed analysis of Li isotopic ratios in both solution and secondary mineral lattices could provide clues about past Martian weathering conditions, including weathering extent, temperature, pH, supersaturation, and evaporation rate of the initial solutions in contact with basalt rocks. In this paper, we discuss ways in which Martian aqueous processes could have lead to Li isotope fractionation. We show that Li isotopic data obtained by future exploration of Mars could be relevant to highlighting different processes of Li isotopic fractionation in the past, and therefore to understanding basalt weathering and environmental conditions early in the planet's history, Data supporting our models and calculations are available as supporting information. The research leading to these results is a contribution from the Project ‘icyMARS’’, funded by the European Research Council, Starting Grant no 307496. This work was also partially supported by the European FEDER program and the Spanish Ministry of Science (MICINN) through the project CGL2011–30079. Comments by R. James and four anonymous reviewers helped us to clarify and strengthen our work

Published

2015

15. Ignimbrite as a substrate for endolithic life in the hyper-arid Atacama Desert: implications for the search for life on Mars

Author

Beatriz Cámara-Gallego, Asunción de los Ríos, Kenneth H. Nealson, Alfonso F. Davila, M. Teresa García-González, Jacek Wierzchos, Sergio Valea, Octavio Artieda, and Carmen Ascaso

Subjects

Search for extraterrestrial life, Phototroph, Mars, Astronomy and Astrophysics, Mars Exploration Program, Substrate (biology), Life on Mars, Arid, Astrobiology, Geophysics, Microbial population biology, Habitat, Space and Planetary Science, Rhyolite, Geology

Abstract

13 páginas, 8 figuras y 3 tables, The hyper-arid core of the Atacama Desert in Chile is considered the driest and most life-limited place on Earth, with few habitats capable of sustaining an active microbial ecosystem. As such, it is one of the best terrestrial analogues of the extreme arid conditions on Mars, and an ideal environment to explore survival and biological adaptation strategies as the environment becomes increasingly dry. Here we show that weakly welded rhyolitic ignimbrites in this desert are abundantly colonized by endolithic cyanobacteria and associated heterotrophic bacteria. We propose that the porous ignimbrite interior provides protection from damaging UV radiation and excessive levels of visible light. Rock porosity also favors cell hydration through water retention after scarce rainfall events, even when the surrounding environment remains stubbornly dry. This is the first known example of an endolithic microbial community colonizing ignimbrite rocks in an extremely dry environment. The existence of a habitat capable of supporting abundant phototrophic and heterotrophic communities in an environment that precludes most life forms suggests that, if similar deposits are found on Mars, these should be considered important targets in the search for life. Indeed, ignimbrite rocks have been tentatively identified in Gale Crater, the landing site of the Mars Science Laboratory (MSL) mission and could be directly analyzed by its rover Curiosity, The authors thank F. Pinto, V. Souza-Egipsy and T. Carnota for technical assistance, and L. Tormo for help with the ESEM, R. Gonzalez with the FRX, M. Juanco with the XRD, and A.L. Duque and D. Gamarra with the MIP work. D. Herrera is thanked for field assistance in the Atacama Desert. We also thank A. Burton for polishing our English. This work was funded by grant CGL2010-16004 and CTM 2009-12838-C04-03 from the Spanish Ministry of Science and Innovation. A.F.D., O.A. and J.W. were supported by Grant NNX12AD61G of the NASA Exobiology program

Published

2013

16. Report of the COSPAR Mars special regions colloquium

Author

Catharine A. Conley, Stephen M. Clifford, Jennifer L. Heldmann, Pericles Stabekis, Gian Gabriele Ori, François Raulin, Frances Westall, William V. Boynton, M. S. Meyer, Llyd E. Wells, J. A. Spry, Charles S. Cockell, Michael H. Hecht, Gerhard Kminek, John Parnell, Horton E. Newsom, Thomas L. Kieft, Daniel Prieur, Erko Stackebrandt, Jorge L. Vago, Alfonso F. Davila, V. Hipkin, Robert Atlas, André Debus, Peter T. Doran, Nadine G. Barlow, Jörn Helbert, Dirk Schulze-Makuch, Mary A. Voytek, David Beaty, Michel Viso, G. Klingelhoefer, John D. Rummel, Gerda Horneck, Michael H. Carr, Agence Spatiale Européenne (ESA), European Space Agency (ESA), East Carolina University [Greenville] (ECU), University of North Carolina System (UNC), The Open University [Milton Keynes] (OU), University of Louisville, Northern Arizona University [Flagstaff], NASA, Jet Prop Lab, CALTECH, 4800 Oak Grove Dr, Pasadena, CA 91109 USA, Lunar and Planetary Laboratory [Tucson] (LPL), University of Arizona, United States Geological Survey (USGS), Lunar and Planetary Institute [Houston] (LPI), NASA Headquarters, NASA Ames Research Center (ARC), Centre National d'Études Spatiales [Toulouse] (CNES), University of Illinois [Chicago] (UIC), University of Illinois System, DLR Institut für Planetenforschung, Deutsches Zentrum für Luft- und Raumfahrt [Berlin] (DLR), Canadian Space Agency (CSA), German Aerospace Center (DLR), New Mexico Institute of Mining and Technology [New Mexico Tech] (NMT), Institute of Physics, University of Mainz, The University of New Mexico [Albuquerque], International Research School of Planetary Sciences [Pescara] (IRSPS), Università degli studi 'G. d'Annunzio' Chieti-Pescara [Chieti-Pescara] (Ud'A), University of Aberdeen, Université de Brest (UBO), Centre National de la Recherche Scientifique (CNRS), Washington State University (WSU), Leibniz-Institut DSMZ-Deutsche Sammlung von Mikroorganismen und Zellkulturen GmbH / Leibniz Institute DSMZ-German Collection of Microorganisms and Cell Cultures (DSMZ), University of Pennsylvania [Philadelphia], Centre de biophysique moléculaire (CBM), Université d'Orléans (UO)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC), Deutsches Zentrum für Luft- und Raumfahrt (DLR), Department of Geology and Petroleum Geology, CEA, Commissariat à l'énergie atomique et aux énergies alternatives (CEA), Laboratoire Interuniversitaire des Systèmes Atmosphériques (LISA (UMR_7583)), Université Paris-Est Créteil Val-de-Marne - Paris 12 (UPEC UP12)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Université d'Orléans (UO)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), and Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris Diderot - Paris 7 (UPD7)-Université Paris-Est Créteil Val-de-Marne - Paris 12 (UPEC UP12)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Planetary protection, Liquid water, Aerospace Engineering, Terrain, BACTERIAL-ACTIVITY, 01 natural sciences, SPACECRAFT SURFACES, Astrobiology, Water-vapor, South-pole snow, 0103 physical sciences, Bacterial activity, Space research, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Martian, Committee on Space Research, COSPAR mars special regions colloquium, Near-surface, Astronomy and Astrophysics, Mars Exploration Program, 15. Life on land, Ground ice, [PHYS.PHYS.PHYS-SPACE-PH]Physics [physics]/Physics [physics]/Space Physics [physics.space-ph], Geophysics, 13. Climate action, Space and Planetary Science, General Earth and Planetary Sciences, High obliquity, Sea-ice, Upper martian surface, Space-craft surfaces, Geology

Abstract

International audience; In this paper we present the findings of a COSPAR Mars Special Regions Colloquium held in Rome in 2007. We review and discuss the definition of Mars Special Regions, the physical parameters used to define Mars Special Regions, and physical features on Mars that can be interpreted as Mars Special Regions. We conclude that any region experiencing temperatures > -25 degrees C for a few hours a year and a water activity > 0.5 can potentially allow the replication of terrestrial microorganisms. Physical features on Mars that can be interpreted as meeting these conditions constitute a Mars Special Region. Based on current knowledge of the martian environment and the conservative nature of planetary protection, the following features constitute Mars Special regions: Gullies and bright streaks associated with them, pasted-on terrain, deep subsurface, dark streaks only on a case-by-case basis, others to be determined. The parameter definition and the associated list of physical features should be re-evaluated on a regular basis.

Published

2010

17. Noachian and more recent phyllosilicates in impact craters on Mars

Author

Oleg Abramov, Livio L. Tornabene, Christoph Gross, Esther R. Uceda, Giuseppe A. Marzo, James M. Dohm, Thomas Kneissl, Alfonso F. Davila, Vincent Chevrier, Ricardo Amils, Ted L. Roush, Christopher P. McKay, P. Gavin, Alberto G. Fairén, J. Alexis P. Rodriguez, Janice L. Bishop, and Dirk Schulze-Makuch

Subjects

Mineral hydration, Minerals, Multidisciplinary, Hot Temperature, Time Factors, Ferric Compounds, Asbestos, Serpentine, Extraterrestrial Environment, Liquid water, Silicates, Spectrum Analysis, Noachian, Mars, Mars Exploration Program, Astrobiology, Impact crater, Chlorides, Planet, Physical Sciences, Aluminum Silicates, Spectrum analysis, Kaolin, Geology

Abstract

Hundreds of impact craters on Mars contain diverse phyllosilicates, interpreted as excavation products of preexisting subsurface deposits following impact and crater formation. This has been used to argue that the conditions conducive to phyllosilicate synthesis, which require the presence of abundant and long-lasting liquid water, were only met early in the history of the planet, during the Noachian period (> 3.6 Gy ago), and that aqueous environments were widespread then. Here we test this hypothesis by examining the excavation process of hydrated minerals by impact events on Mars and analyzing the stability of phyllosilicates against the impact-induced thermal shock. To do so, we first compare the infrared spectra of thermally altered phyllosilicates with those of hydrated minerals known to occur in craters on Mars and then analyze the postshock temperatures reached during impact crater excavation. Our results show that phyllosilicates can resist the postshock temperatures almost everywhere in the crater, except under particular conditions in a central area in and near the point of impact. We conclude that most phyllosilicates detected inside impact craters on Mars are consistent with excavated preexisting sediments, supporting the hypothesis of a primeval and long-lasting global aqueous environment. When our analyses are applied to specific impact craters on Mars, we are able to identify both pre- and postimpact phyllosilicates, therefore extending the time of local phyllosilicate synthesis to post-Noachian times.

Published

2010

18. Scientific field training for human planetary exploration

Author

J. Heaton, Allyson L. Brady, D. Williams, Bernard E. Laval, Dale T. Andersen, P. Nuytten, Greg F. Slater, Margarita M. Marinova, Gordon R. Osinski, M. Delaney, M. L. Gernhardt, R. Shepard, C. P. McKay, Alberto G. Fairén, G.L. Warman, Alfonso F. Davila, M. Reay, D. Reid, Benjamin R. Cowie, Dirk Schulze-Makuch, Z. Cardman, R. Arnold, Alexander L. Forrest, Darlene S. S. Lim, and Terrence Fong

Subjects

Space and Planetary Science, Computer science, Intrinsic motivation, Astronomy and Astrophysics, Cognition, Engineering ethics, Informal learning, Transfer of learning, Social learning, Curriculum, Planetary exploration, Astronaut training

Abstract

Forthcoming human planetary exploration will require increased scientific return (both in real time and post-mission), longer surface stays, greater geographical coverage, longer and more frequent EVAs, and more operational complexities than during the Apollo missions. As such, there is a need to shift the nature of astronauts’ scientific capabilities to something akin to an experienced terrestrial field scientist. To achieve this aim, the authors present a case that astronaut training should include an Apollo-style curriculum based on traditional field school experiences, as well as full immersion in field science programs. Herein we propose four Learning Design Principles (LDPs) focused on optimizing astronaut learning in field science settings. The LDPs are as follows: (1) LDP#1: Provide multiple experiences: varied field science activities will hone astronauts’ abilities to adapt to novel scientific opportunities (2) LDP#2: Focus on the learner: fostering intrinsic motivation will orient astronauts towards continuous informal learning and a quest for mastery (3) LDP#3: Provide a relevant experience—the field site: field sites that share features with future planetary missions will increase the likelihood that astronauts will successfully transfer learning (4) LDP#4: Provide a social learning experience—the field science team and their activities: ensuring the field team includes members of varying levels of experience engaged in opportunities for discourse and joint problem solving will facilitate astronauts’ abilities to think and perform like a field scientist. The proposed training program focuses on the intellectual and technical aspects of field science, as well as the cognitive manner in which field scientists experience, observe and synthesize their environment. The goal of the latter is to help astronauts develop the thought patterns and mechanics of an effective field scientist, thereby providing a broader base of experience and expertise than could be achieved from field school alone. This will enhance their ability to execute, explore and adapt as in-field situations require.

Published

2010

19. New evidence for a magmatic influence on the origin of Valles Marineris, Mars

Author

Jean-Pierre Williams, Alberto G. Fairén, J. C. Ferris, Dirk Schulze-Makuch, Robert C. Anderson, Patrick C. McGuire, James M. Dohm, Javier Ruiz, Trent M. Hare, Kennth L. Tanaka, Alfonso F. Davila, William V. Boynton, Shawn J. Wheelock, Hirdy Miyamoto, Victor R. Baker, and Goro Komatsu

Subjects

geography, geography.geographical_feature_category, Geodinámica, 010504 meteorology & atmospheric sciences, Outcrop, Amazonian, Noachian, Geochemistry, 15. Life on land, 01 natural sciences, Geophysics, Volcano, Geochemistry and Petrology, 0103 physical sciences, Magmatism, Magma, Caldera, 010303 astronomy & astrophysics, Geomorphology, Geology, 0105 earth and related environmental sciences, Tharsis

Abstract

In this paper, we show that the complex geological evolution of Valles Marineris, Mars, has been highly influenced by the manifestation of magmatism (e.g., possible plume activity). This is based on a diversity of evidence, reported here, for the central part, Melas Chasma, and nearby regions, including uplift, loss of huge volumes of material, flexure, volcanism, and possible hydrothermal and endogenic-induced outflow channel activity. Observations include: (1) the identification of a new N50 km-diameter caldera/vent-like feature on the southwest flank of Melas, which is spatially associated with a previously identified center of tectonic activity using Viking data; (2) a prominent topographic rise at the central part of Valles Marineris, which includes Melas Chasma, interpreted to mark an uplift, consistent with faults that are radial and concentric about it; (3) HiRISE-identified landforms along the floor of the southeast part of Melas Chasma that are interpreted to reveal a volcanic field; (4) CRISM identification of sulfate-rich outcrops, which could be indicative of hydrothermal deposits; (5) GRS K/Th signature interpreted as water–magma interactions and/ or variations in rock composition; and (6) geophysical evidence that may indicate partial compensation of the canyon and/or higher density intrusives beneath it. Long-term magma, tectonic, and water interactions (Late Noachian into the Amazonian), albeit intermittent, point to an elevated life potential, and thus Valles Marineris is considered a prime target for future life detection missions.

Published

2009

20. Evidence for Amazonian acidic liquid water on Mars - A reinterpretation of MER mission results

Author

Roberto Furfaro, Alberto G. Fairén, Christopher P. McKay, Ricardo Amils, Alexis P. Rodriguez, Alfonso F. Davila, Dirk Schulze-Makuch, Esther R. Uceda, and Wolfgang Fink

Subjects

Meridiani Planum, Water on Mars, Amazonian, Geochemistry, Astronomy and Astrophysics, Weathering, Mars Exploration Program, engineering.material, Hematite, Astrobiology, Space and Planetary Science, visual_art, Jarosite, engineering, visual_art.visual_art_medium, Composition of Mars, Geology

Abstract

The Mars Exploration Rover (MER) missions have confirmed aqueous activity on Mars. Here we review the analyses of the field-based MER data, and conclude that some weathering processes in Meridiani Planum and Gusev crater are better explained by late diagenetic water-rock interactions than by early diagenesis only. At Meridiani, the discovery of jarosite by MER-1 Opportunity indicates acidic aqueous activity, evaporation, and desiccation of rock materials. MER-based information, placed into the context of published data, point to local and limited aqueous activity during geologically recent times in Meridiani. Pre-Amazonian environmental changes (including important variations in the near-surface groundwater reservoirs, impact cratering, and global dust storms and other pervasive wind-related erosion) are too extreme for pulverulent jarosite to survive over extended time periods, and therefore we argue instead that jarosite deposits must have formed in a climatically more stable period. Any deposits of pre-existent concretionary jarosite surviving up to the Amazonian would not have reached completion in the highly saline and acidic brines occurring at Meridiani. MER-2 Spirit has also revealed evidence for local and limited Amazonian aqueous environmental conditions in Gusev crater, including chemical weathering leading to goethite and hematite precipitation, rock layering, and chemical enhancement of Cl, S, Br, and oxidized iron in rocks and soils. The estimated relative age of the impact crater materials in Gusev indicates that these processes have taken place during the last 2 billion years. We conclude that minor amounts of shallow acidic liquid water have been present on the surface of Mars at local scales during the Amazonian Period.

Published

2009

21. Subsurface formation of oxidants on Mars and implications for the preservation of organic biosignatures

Author

Alberto G. Fairén, Alfonso F. Davila, Carol R. Stoker, L. Gago-Duport, Dirk Schulze-Makuch, Ricardo Amils, Darlene Lim, Christopher P. McKay, J. Zavaleta, and Rosalba Bonaccorsi

Subjects

Martian, geography, geography.geographical_feature_category, Pyrite, Geochemistry, Mars, Aquifer, Mars Exploration Program, Aqueous oxidation, engineering.material, Life on Mars, Hydrogen peroxide, Anoxic waters, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Oxidizing agent, Organic compounds, Earth and Planetary Sciences (miscellaneous), engineering, Groundwater, Geology

Abstract

8 pages, 4 figures.-- Printed version published Jul 30, 2008., Hydrogen peroxide can form through the interaction of pyrite and anoxic water. The oxidation of pyrite results in the precipitation of sulfates and iron oxides, high redox potentials (~ 1000 mV) and acidic pH (3–4). The oxidative potential of the resultant solution may be responsible for the oxidation of organic compounds, as observed in the subsurface of the Rio Tinto Mars analog. On Mars subsurface migration of groundwater interacting with volcanogenic massive pyrite deposits would have mobilized acidic and oxidizing fluids through large portions of the crust, resulting in the widespread deposition of sulfates and iron oxides. This groundwater could have leached substantial volumes of aquifer material and crustal rocks, thereby erasing any organic compounds possibly down to depths of hundreds of meters. Therefore, the preservation of organic biosignatures must have been severely constrained in the portions of the ancient Martian crust that were exposed to aqueous processes, calling for a redefinition of the future targets in the search for biomolecular traces of life on Mars., AFD, AGF and RB wish to thank the Oak Ridge Associated Universities for financial support. We wish to thank the MARTE team for obtaining the data of the project used in this work and also the funds from the Centro de Astrobiologia and the NASA ASTEP program, devoted to the development of the project.

Published

2008

22. The Next Phase in Our Search for Life:An Expert Discussion.

Author

Moderator:Christopher P. McKay, Participants:Dirk Schulze-Makuch, Penelope Jane Boston, Inge L. ten Kate, Alfonso F. Davila, and Everett Shock

Published

2011

23. Astrobiology through the Ages of Mars: The Study of Terrestrial Analogues to Understand the Habitability of Mars.

Author

Alberto G. Fairén, Alfonso F. Davila, Darlene Lim, Nathan Bramall, Rosalba Bonaccorsi, Jhony Zavaleta, Esther R. Uceda, Carol Stoker, Jacek Wierzchos, James M. Dohm, Ricardo Amils, Dale Andersen, and Christopher P. McKay

Subjects

*SPACE biology, *MARS (Planet), *GEOLOGY, *ARID regions, *ARTIFICIAL atmospheres (Space environment), *GEOCHEMISTRY, *SPACE flight

Abstract

AbstractMars has undergone three main climatic stages throughout its geological history, beginning with a water-rich epoch, followed by a cold and semi-arid era, and transitioning into present-day arid and very cold desert conditions. These global climatic eras also represent three different stages of planetary habitability: an early, potentially habitable stage when the basic requisites for life as we know it were present (liquid water and energy); an intermediate extreme stage, when liquid solutions became scarce or very challenging for life; and the most recent stage during which conditions on the surface have been largely uninhabitable, except perhaps in some isolated niches. Our understanding of the evolution of Mars is now sufficient to assign specific terrestrial environments to each of these periods. Through the study of Mars terrestrial analogues, we have assessed and constrained the habitability conditions for each of these stages, the geochemistry of the surface, and the likelihood for the preservation of organic and inorganic biosignatures. The study of these analog environments provides important information to better understand past and current mission results as well as to support the design and selection of instruments and the planning for future exploratory missions to Mars. Key Words: Mars—Astrobiology—Mars analogues—Climatic evolution of Mars. Astrobiology 10, 821–843. [ABSTRACT FROM AUTHOR]

Published

2010

24. New Priorities in the Robotic Exploration of Mars: The Case for In SituSearch for Extant Life.

Author

Alfonso F. Davila, Mark Skidmore, Alberto G. Fairén, Charles Cockell, and Dirk Schulze-Makuch

Published

2010

25. Hygroscopic Salts and the Potential for Life on Mars.

Author

Alfonso F. Davila, Luis Gago Duport, Riccardo Melchiorri, Jochen Jänchen, Sergio Valea, Asunción de los Rios, Alberto G. Fairén, Diedrich Möhlmann, Christopher P. McKay, Carmen Ascaso, and Jacek Wierzchos

Subjects

*EXTRATERRESTRIAL life, *SPACE microbiology, *CLIMATOLOGY, *SODIUM chlorate, *MARTIAN surface, *MARS (Planet)

Abstract

AbstractHygroscopic salts have been detected in soils in the northern latitudes of Mars, and widespread chloride-bearing evaporitic deposits have been detected in the southern highlands. The deliquescence of hygroscopic minerals such as chloride salts could provide a local and transient source of liquid water that would be available for microorganisms on the surface. This is known to occur in the Atacama Desert, where massive halite evaporites have become a habitat for photosynthetic and heterotrophic microorganisms that take advantage of the deliquescence of the salt at certain relative humidity (RH) levels. We modeled the climate conditions (RH and temperature) in a region on Mars with chloride-bearing evaporites, and modeled the evolution of the water activity (aw) of the deliquescence solutions of three possible chloride salts (sodium chloride, calcium chloride, and magnesium chloride) as a function of temperature. We also studied the water absorption properties of the same salts as a function of RH. Our climate model results show that the RH in the region with chloride-bearing deposits on Mars often reaches the deliquescence points of all three salts, and the temperature reaches levels above their eutectic points seasonally, in the course of a martian year. The awof the deliquescence solutions increases with decreasing temperature due mainly to the precipitation of unstable phases, which removes ions from the solution. The deliquescence of sodium chloride results in transient solutions with awcompatible with growth of terrestrial microorganisms down to 252 K, whereas for calcium chloride and magnesium chloride it results in solutions with awbelow the known limits for growth at all temperatures. However, taking the limits of awused to define special regions on Mars, the deliquescence of calcium chloride deposits would allow for the propagation of terrestrial microorganisms at temperatures between 265 and 253 K, and for metabolic activity (no growth) at temperatures between 253 and 233 K. Key Words: Hygroscopic salts—Evaporites—Water activity—Temperature—Endoliths—Atacama Desert—Deliquescence—Mars—Life. Astrobiology 10, 617–628. [ABSTRACT FROM AUTHOR]

Published

2010

26. Noachian and more recent phyllosilicates in impact craters on Mars.

Author

Alberto G. Fair&#00E9;n, Vincent Chevrier, Oleg Abramov, Giuseppe A. Marzo, Patricia Gavin, Alfonso F. Davila, Livio L. Tornabene, Janice L. Bishop, Ted L. Roush, Christoph Gross, Thomas Kneissl, Esther R. Uceda, James M. Dohm, Dirk Schulze-Makuch, J. Alexis P. Rodr&#00ED;guez, Ricardo Amils, and Christopher P. McKay

Subjects

MARTIAN craters, PHYLLOSILICATES, IMPACT craters, MARS (Planet), SPECTRUM analysis

Abstract

Hundreds of impact craters on Mars contain diverse phyllosilicates, interpreted as excavation products of preexisting subsurface deposits following impact and crater formation. This has been used to argue that the conditions conducive to phyllosilicate synthesis, which require the presence of abundant and long-lasting liquid water, were only met early in the history of the planet, during the Noachian period (> 3.6 Gy ago), and that aqueous environments were widespread then. Here we test this hypothesis by examining the excavation process of hydrated minerals by impact events on Mars and analyzing the stability of phyllosilicates against the impact-induced thermal shock. To do so, we first compare the infrared spectra of thermally altered phyllosilicates with those of hydrated minerals known to occur in craters on Mars and then analyze the postshock temperatures reached during impact crater excavation. Our results show that phyllosilicates can resist the postshock temperatures almost everywhere in the crater, except under particular conditions in a central area in and near the point of impact. We conclude that most phyllosilicates detected inside impact craters on Mars are consistent with excavated preexisting sediments, supporting the hypothesis of a primeval and long-lasting global aqueous environment. When our analyses are applied to specific impact craters on Mars, we are able to identify both pre- and post-impact phyllosilicates, therefore extending the time of local phyllosilicate synthesis to post-Noachian times. [ABSTRACT FROM AUTHOR]

Published

2010

27. In situ metabolism in halite endolithic microbial communities of the hyperarid Atacama Desert

Author

Alfonso F Davila, Ian eHawes, Jonathan eGarcía Araya, Diego R Gelsinger, Jocelyne eDiRuggiero, Carmen eAscaso, Anne eOsano, and Jacek eWierzchos

Subjects

Metabolism, Photosynthesis, Atacama Desert, HALITE, deliquescence, endolithic community, Microbiology, QR1-502

Abstract

The Atacama Desert of northern Chile is one of the driest regions on Earth, with areas that exclude plants and where soils have extremely low microbial biomass. However, in the driest parts of the desert there are microorganisms that colonize the interior of halite nodules in fossil continental evaporites, where they are sustained by condensation of atmospheric water triggered by the salt substrate. Using a combination of in situ observations of variable chlorophyll fluorescence and controlled laboratory experiments, we show that this endolithic community is capable of carbon fixation both through oxygenic photosynthesis and potentially ammonia oxidation. We also present evidence that photosynthetic activity is finely tuned to moisture availability and solar insolation and can be sustained for days, and perhaps longer, after a wetting event. This is the first demonstration of in situ active metabolism in the hyperarid core of the Atacama Desert, and it provides the basis for proposing a self-contained, endolithic community that relies exclusively on non-rainfall sources of water. Our results contribute to an increasing body of evidence that even in hyperarid environments active metabolism, adaptation and growth can occur in highly specialized microhabitats.

Published

2015