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2. Climate and energy balance of the ground in University Valley, Antarctica

Author

Margarita M. Marinova, Christopher P. McKay, Jennifer L. Heldmann, Jacqueline Goordial, Denis Lacelle, Wayne H. Pollard, and Alfonso F. Davila

Subjects
Geology, Oceanography, Ecology, Evolution, Behavior and Systematics
Abstract

We report 3 years of data from one meteorological and three smaller stations in University Valley, a high-elevation (1677 m) site in the Dry Valleys of Antarctica with extensive dry permafrost. Mean air temperature was -23.4°C. Summer air temperatures were virtually always < 0°C and were consistent with the altitude lapse rate and empirical relationships between summer temperature, distance from the coast and elevation. The measured frost point (-22.5°C) at the 42 cm deep ice table is equal to the surface frost point and above the atmospheric frost point (-29.6°C), providing direct evidence that surface conditions control ground ice depth. Observed peak surface soil temperatures reach 6°C for ice-cemented ground > 15 cm deep but stay < 0°C when it is shallower. We develop an energy balance model tuned to this rocky and dry environment. We find that differences in peak soil surface temperatures are primarily due to the higher thermal diffusivity of ice-cemented ground compared to dry soil. Sensitivity studies show that expected natural variability is insufficient for melt to form and significant excursions from current conditions are required. The site's ice table meets the criteria for a Special Region on Mars, with 30% of the year > -18°C and water activity > 0.6.

Published
2022

3. Requirements for Portable Instrument Suites during Human Scientific Exploration of Mars

Author

Alexander Sehlke, Zara L Mirmalek, David Burtt, Christopher W. Haberle, Delia Santiago-Materese, Shannon E. Kobs Nawotniak, Scott S. Hughes, W. Brent Garry, Nathan Bramall, Adrian J. Brown, Jennifer L. Heldmann, and Darlene S.S. Lim

Subjects
Exobiology
Abstract

Human explorers on the surface of Mars will have access to a far wider array of scientific tools than previous crewed planetary exploration missions, but not every tool will be compatible with the restrictions of this exploration. Spectrometers on flyby, orbital, and landed missions are currently used to determine the composition and mineralogy of geological materials of various types and sizes, from small fragments to celestial bodies in the solar system. Handheld spectrometers that are capable of in situ analyses are already used for geological exploration on Earth; however, their usefulness for human exploration missions and how data from multiple handheld instruments could be combined to enhance scientific return must be further evaluated. As part of the Biologic Analog Science Associated with Lava Terrains (BASALT) research project, we incorporated two handheld instruments, a visible-near infrared spectrometer and an X-Ray Fluorescence spectrometer, into simulated Mars exploration missions conducted on basaltic terrains in Idaho and Hawai'i. To understand the data quality provided by these handheld spectrometers, we evaluated their performance under varying conditions of measurement time, distance, angle, atmosphere, and sample matrix, and we compared data quality between handheld instruments and laboratory techniques. Here, we summarize these findings, provide guidelines and requirements on how to effectively incorporate these instruments into human exploration missions to Mars, and posit that future iterations of these instruments will be beneficial for enhancing science returned from human exploration missions.

Published
2019
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5. Mission Architecture Using the SpaceX Starship Vehicle to Enable a Sustained Human Presence on Mars

Author

Jennifer L. Heldmann, Margarita M. Marinova, Darlene S.S. Lim, David Wilson, Peter Carrato, Keith Kennedy, Ann Esbeck, Tony Anthony Colaprete, Richard C. Elphic, Janine Captain, Kris Zacny, Leo Stolov, Boleslaw Mellerowicz, Joseph Palmowski, Ali M. Bramson, Nathaniel Putzig, Gareth Morgan, Hanna Sizemore, and Josh Coyan

Subjects
Tourism, Leisure and Hospitality Management, Energy Engineering and Power Technology, Aerospace Engineering, Astronomy and Astrophysics, Safety, Risk, Reliability and Quality
Abstract

A main goal of human space exploration is to develop humanity into a multi-planet species where civilization extends beyond planet Earth. Establishing a self-sustaining human presence on Mars is key to achieving this goal.

Published
2022

6. Red Dragon Drill Missions to Mars

Author

Jennifer L Heldmann, Carol R Stoker, Andrew Gonzales, Christopher P Mckay, Alfonso Davila, Brian J Glass, Larry Lemke, Gale Paulsen, David Wilson, and Kris Zacny

Subjects
Lunar And Planetary Science And Exploration
Abstract

We present the concept of using a variant of a Space Exploration Technologies Corporation (SpaceX) Dragon space capsule as a low-cost, large-capacity, near-term, Mars lander (dubbed "Red Dragon") for scientific and human precursor missions. SpaceX initially designed the Dragon capsule for flight near Earth, and Dragon has successfully flown many times to low-Earth orbit (LEO) and successfully returned the Dragon spacecraft to Earth. Here we present capsule hardware modifications that are required to enable flight to Mars and operations on the martian surface. We discuss the use of the Dragon system to support NASA Discovery class missions to Mars and focus in particular on Dragon's applications for drilling missions. We find that a Red Dragon platform is well suited for missions capable of drilling deeper on Mars (at least 2 m) than has been accomplished to date due to its ability to land in a powered controlled mode, accommodate a long drill string, and provide payload space for sample processing and analysis. We show that a Red Dragon drill lander could conduct surface missions at three possible targets including the ice-cemented ground at the Phoenix landing site (68degN), the subsurface ice discovered near the Viking 2 (49degN) site by fresh impact craters, and the dark sedimentary subsurface material at the Curiosity site (4.5degS).

Published
2017
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8. Basaltic Terrains in Idaho and Hawai‘i as Planetary Analogs for Mars Geology and Astrobiology

Author

Shannon E. Kobs Nawotniak, Jennifer L. Heldmann, Samuel J. Payler, W. Brent Garry, Allyson L. Brady, Darlene S. S. Lim, Scott S. Hughes, Adam R. H. Stevens, Alexander Sehlke, Charles S. Cockell, Richard C. Elphic, and Christopher W. Haberle

Subjects
Extraterrestrial Environment, 010504 meteorology & atmospheric sciences, Lithology, Idaho, Earth science, Mars, Terrain, Volcanic Eruptions, Planetary geology, Exploration of Mars, 01 natural sciences, Hawaii, Field regions, Exobiology, 0103 physical sciences, 010303 astronomy & astrophysics, Research Articles, 0105 earth and related environmental sciences, Basalt, geography, geography.geographical_feature_category, Silicates, Mars Exploration Program, Agricultural and Biological Sciences (miscellaneous), Planetary analogs, Volcano, Space and Planetary Science, Volcanic terrains, Rock alteration, Geology
Abstract

Field research target regions within two basaltic geologic provinces are described as Earth analogs to Mars. Regions within the eastern Snake River Plain of Idaho and the Big Island of Hawai‘i, the United States, provinces that represent analogs of present-day and early Mars, respectively, were evaluated on the basis of geologic settings, rock lithology and geochemistry, rock alteration, and climate. Each of these factors provides rationale for the selection of specific targets for field research in five analog target regions: (1) Big Craters and (2) Highway lava flows at Craters of the Moon National Monument and Preserve, Idaho, and (3) Mauna Ulu low shield, (4) Kīlauea Iki lava lake, and (5) Kīlauea caldera in the Kīlauea Volcano summit region and the East Rift Zone of Hawai‘i. Our evaluation of compositional and textural attributes, as well as the effects of syn- and posteruptive rock alteration, shows that basaltic terrains in Idaho and Hawai‘i provide a way to characterize the geology and major geologic substrates that host biological activity of relevance to Mars exploration. This work provides the foundation to better understand the scientific questions related to the habitability of basaltic terrains, the rationale behind selecting analog field targets, and their applicability as analogs to Mars.

Published
2019

9. Requirements for Portable Instrument Suites during Human Scientific Exploration of Mars

Author

Delia Santiago-Materese, N. Bramall, Zara Mirmalek, Alexander Sehlke, W. Brent Garry, Shannon E. Kobs Nawotniak, Scott S. Hughes, David Burtt, Adrian J. Brown, Darlene S. S. Lim, Christopher W. Haberle, and Jennifer L. Heldmann

Subjects
Extraterrestrial Environment, 010504 meteorology & atmospheric sciences, Computer science, Mars, Guidelines as Topic, Terrain, Exploration of Mars, 01 natural sciences, Exobiology, 0103 physical sciences, Operations, Humans, Geological exploration, Handheld spectrometers, 010303 astronomy & astrophysics, Research Articles, 0105 earth and related environmental sciences, Scientific instrument, Spectrometer, Atmosphere, Silicates, Spectrum Analysis, Mars Exploration Program, Space Flight, Agricultural and Biological Sciences (miscellaneous), Extra-vehicular activities, Space and Planetary Science, Data quality, Systems engineering, Exploration, Basalt, Mobile device
Abstract

Human explorers on the surface of Mars will have access to a far wider array of scientific tools than previous crewed planetary exploration missions, but not every tool will be compatible with the restrictions of this exploration. Spectrometers on flyby, orbital, and landed missions are currently used to determine the composition and mineralogy of geological materials of various types and sizes, from small fragments to celestial bodies in the solar system. Handheld spectrometers that are capable of in situ analyses are already used for geological exploration on Earth; however, their usefulness for human exploration missions and how data from multiple handheld instruments could be combined to enhance scientific return must be further evaluated. As part of the Biologic Analog Science Associated with Lava Terrains (BASALT) research project, we incorporated two handheld instruments, a visible-near infrared spectrometer and an X-Ray Fluorescence spectrometer, into simulated Mars exploration missions conducted on basaltic terrains in Idaho and Hawai'i. To understand the data quality provided by these handheld spectrometers, we evaluated their performance under varying conditions of measurement time, distance, angle, atmosphere, and sample matrix, and we compared data quality between handheld instruments and laboratory techniques. Here, we summarize these findings, provide guidelines and requirements on how to effectively incorporate these instruments into human exploration missions to Mars, and posit that future iterations of these instruments will be beneficial for enhancing science returned from human exploration missions.

Published
2019

10. The BASALT Research Program: Designing and Developing Mission Elements in Support of Human Scientific Exploration of Mars

Author

Allyson L. Brady, David Lees, Scott S. Hughes, Steven P. Chappell, Richard C. Elphic, Shannon E. Kobs Nawotniak, Christopher W. Haberle, Jennifer L. Heldmann, Michael J. Miller, Adam R. H. Stevens, Charles S. Cockell, Zara Mirmalek, M. Downs, Darlene S. S. Lim, Matthew J. Miller, Andrew F. J. Abercromby, Kara H. Beaton, Alexander Sehlke, and Samuel J. Payler

Subjects
Basalt, Research program, Engineering, 010504 meteorology & atmospheric sciences, business.industry, Habitability, Science, Analog, Mars, Spaceflight, Mars Exploration Program, Scientific field, Exploration of Mars, 01 natural sciences, Agricultural and Biological Sciences (miscellaneous), BASALT, Space and Planetary Science, 0103 physical sciences, Systems engineering, Operations, business, 010303 astronomy & astrophysics, Research Articles, 0105 earth and related environmental sciences
Abstract

The articles associated with this Special Collection focus on the NASA BASALT (Biologic Analog Science Associated with Lava Terrains) Research Program, which aims at answering the question, “How do we support and enable scientific exploration during human Mars missions?” To answer this the BASALT team conducted scientific field studies under simulated Mars mission conditions to both broaden our understanding of the habitability potential of basalt-rich terrains on Mars and examine the effects of science on current Mars mission concepts of operations. This article provides an overview of the BASALT research project, from the science, to the operational concepts that were tested and developed, to the technical capabilities that supported all elements of the team's research. Further, this article introduces the 12 articles that are included in this Special Collection.

Published
2019

11. Spatter stability: constraining accumulation rates and temperature conditions with experimental bomb morphology

Author

Karen S. Harpp, E. Rader, R. Wysocki, M. Myers, M. Bosselait, and Jennifer L. Heldmann

Subjects
Basalt, geography, geography.geographical_feature_category, Yield (engineering), 010504 meteorology & atmospheric sciences, Lead (sea ice), 010502 geochemistry & geophysics, 01 natural sciences, Volcanic glass, Rheology, Volcano, Geochemistry and Petrology, Clastic rock, Compression (geology), Petrology, Geology, 0105 earth and related environmental sciences
Abstract

We have developed the first experimental methodology to create a volcanic spatter pile using molten basalt. This method permits reproduction of thermal conditions that yield the wide variety of spatter morphologies observed in nature. The morphology of the clasts is most strongly controlled by the time the clast spends above the glass transition temperature, which is in turn affected by the rate of accumulation and cooling of the deposit. Also, spatter piles that remain hotter over longer durations experience increased fusion between clasts, less void space between clasts, and generally larger aspect ratios. Our experimental method successfully replicated natural microcrystal textures, rheology, and clast size. Work is still therefore required to achieve realistic vesicle distribution and deposit void space. Based on presented experimental work, we estimate emplacement conditions of Southern Idaho spatter vents to have been ~ 850–900 °C, with eruption temperatures closer to 1000–1100 °C. The rapid decrease from eruption temperature to effective emplacement temperature is the result of clast flight as well as equilibrating with the cooler surrounding material. The morphology of the natural clasts matches experiments that have accumulation rates of 2.5–4.5 m/h, which also is consistent with the few measurements made at active eruptions. Finally, we provide a constraint on the temperatures and accumulation rates that can lead to the construction of fused spatter features, as well as provide the steps for future experiments to investigate other aspects (such as compression, impact, and larger sizes) of spatter formation by adapting our methodology.

Published
2020

12. Variability of Spatter Morphology in Pyroclastic Deposits in Southern Idaho, as Correlated to Thermal Conditions and Eruptive Environment

Author

E. Rader, Jennifer L. Heldmann, and S. E. Kobs Nawotniak

Subjects
Morphology (linguistics), 010504 meteorology & atmospheric sciences, Thermal, Geochemistry, General Earth and Planetary Sciences, Pyroclastic rock, Mars Exploration Program, Environmental Science (miscellaneous), 010502 geochemistry & geophysics, 01 natural sciences, Geology, 0105 earth and related environmental sciences
Published
2018

13. Contrasting Regional Soil Alteration Across the Topographic Dichotomy of Mars

Author

Kyeong Ja Kim, C. Fralick, D. R. Hood, Suniti Karunatillake, Lujendra Ojha, Jennifer L. Heldmann, Olivier Gasnault, B. Dutrow, Amy J. Williams, S. Kobs, Institut de recherche en astrophysique et planétologie (IRAP), Institut national des sciences de l'Univers (INSU - CNRS)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Observatoire Midi-Pyrénées (OMP), Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Centre National de la Recherche Scientifique (CNRS), Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), and Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Centre National de la Recherche Scientifique (CNRS)

Subjects
010504 meteorology & atmospheric sciences, Habitability, Earth science, Martian soil, Mars Exploration Program, 01 natural sciences, Geophysics, [SDU.STU.PL]Sciences of the Universe [physics]/Earth Sciences/Planetology, 0103 physical sciences, General Earth and Planetary Sciences, 010303 astronomy & astrophysics, Geology, ComputingMilieux_MISCELLANEOUS, 0105 earth and related environmental sciences
Abstract

International audience

Published
2019

14. Phreatic explosions during basaltic fissure eruptions: Kings Bowl lava field, Snake River Plain, USA

Author

Christopher W. Haberle, William Brent Garry, Scott S. Hughes, Jennifer L. Heldmann, Shannon E. Kobs Nawotniak, Derek W. G. Sears, Darlene S. S. Lim, Christian Borg, and Eric H. Christiansen

Subjects
Basalt, geography, geography.geographical_feature_category, Olivine, 010504 meteorology & atmospheric sciences, Lithology, Lava, Fissure, Geochemistry, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, medicine.anatomical_structure, Lava field, Geochemistry and Petrology, medicine, engineering, Ejecta, Geology, Phreatic, 0105 earth and related environmental sciences
Abstract

Physical and compositional measurements are made at the ~ 7 km-long (~ 2200 years B.P.) Kings Bowl basaltic fissure system and surrounding lava field in order to further understand the interaction of fissure-fed lavas with phreatic explosive events. These assessments are intended to elucidate the cause and potential for hazards associated with phreatic phases that occur during basaltic fissure eruptions. In the present paper we focus on a general understanding of the geological history of the site. We utilize geospatial analysis of lava surfaces, lithologic and geochemical signatures of lava flows and explosively ejected blocks, and surveys via ground observation and remote sensing. Lithologic and geochemical signatures readily distinguish between Kings Bowl and underlying pre-Kings Bowl lava flows, both of which comprise phreatic ejecta from the Kings Bowl fissure. These basalt types, as well as neighboring lava flows from the contemporaneous Wapi lava field and the older Inferno Chasm vent and outflow channel, fall compositionally within the framework of eastern Snake River Plain olivine tholeiites. Total volume of lava in the Kings Bowl field is estimated to be ~ 0.0125 km3, compared to a previous estimate of 0.005 km3. The main (central) lava lake lost a total of ~ 0.0018 km3 of magma by either drain-back into the fissure system or breakout flows from breached levees. Phreatic explosions along the Kings Bowl fissure system occurred after magma supply was cut off, leading to fissure evacuation, and were triggered by magma withdrawal. The fissure system produced multiple phreatic explosions and the main pit is accompanied by others that occur as subordinate pits and linear blast corridors along the fissure. The drop in magma supply and the concomitant influx of groundwater were necessary processes that led to the formation of Kings Bowl and other pits along the fissure. A conceptual model is presented that has relevance to the broader range of low-volume, monogenetic basaltic fissure eruptions on Earth, the Moon and other planetary bodies.

Published
2018

15. Terrestrial analogues for lunar impact melt flows

Author

R. C. Elphic, Joshua L. Bandfield, Jennifer L. Heldmann, Lynn M. Carter, S. E. Kobs Nawotniak, Catherine D. Neish, J. R. Skok, D. S. S. Lim, Scott S. Hughes, William Brent Garry, Christopher W. Hamilton, E. I. Schaefer, and Gordon R. Osinski

Subjects
Basalt, Lunar craters, 010504 meteorology & atmospheric sciences, Lava, Astronomy and Astrophysics, Volcanism, 01 natural sciences, National monument, Impact crater, Space and Planetary Science, 0103 physical sciences, Fluid dynamics, Surface roughness, Petrology, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences
Abstract

Lunar impact melt deposits have unique physical properties. They have among the highest observed radar returns at S-Band (12.6 cm wavelength), implying that they are rough at the decimeter scale. However, they are also observed in high-resolution optical imagery to be quite smooth at the meter scale. These characteristics distinguish them from well-studied terrestrial analogues, such as Hawaiian pāhoehoe and ʻaʻā lava flows. The morphology of impact melt deposits can be related to their emplacement conditions, so understanding the origin of these unique surface properties will help to inform us as to the circumstances under which they were formed. In this work, we seek to find a terrestrial analogue for well-preserved lunar impact melt flows by examining fresh lava flows on Earth. We compare the radar return and high-resolution topographic variations of impact melt flows to terrestrial lava flows with a range of surface textures. The lava flows examined in this work range from smooth Hawaiian pāhoehoe to transitional basaltic flows at Craters of the Moon (COTM) National Monument and Preserve in Idaho to rubbly and spiny pāhoehoe-like flows at the recent eruption at Holuhraun in Iceland. The physical properties of lunar impact melt flows appear to differ from those of all the terrestrial lava flows studied in this work. This may be due to (a) differences in post-emplacement modification processes or (b) fundamental differences in the surface texture of the melt flows due to the melts’ unique emplacement and/or cooling environment. Information about the surface properties of lunar impact melt deposits will be critical for future landed missions that wish to sample these materials.

Published
2017

17. Site selection and traverse planning to support a lunar polar rover mission: A case study at Haworth Crater

Author

David Lees, Andrew McGovern, Anthony Colaprete, Jennifer L. Heldmann, Matthew Deans, Richard C. Elphic, Ben Bussey, and Ross A. Beyer

Subjects
Traverse, 010504 meteorology & atmospheric sciences, Science and engineering, Site selection, Aerospace Engineering, Solar illumination, 01 natural sciences, Astrobiology, Impact crater, 0103 physical sciences, Polar, Motion planning, Scale (map), 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences
Abstract

Studies of lunar polar volatile deposits are of interest for scientific purposes to understand the nature and evolution of the volatiles, and also for exploration reasons as a possible in situ resource to enable long term human exploration and settlement of the Moon. Both theoretical and observational studies have suggested that significant quantities of volatiles exist in the polar regions, although the lateral and horizontal distribution remains unknown at the km scale and finer resolution. A lunar polar rover mission is required to further characterize the distribution, quantity, and character of lunar polar volatile deposits at these higher spatial resolutions. Here we present a case study for NASA's Resource Prospector (RP) mission concept for a lunar polar rover and utilize this mission architecture and associated constraints to evaluate whether a suitable landing site exists to support an RP flight mission. We evaluate the landing site criteria to characterize the Haworth Crater region in terms of expected hydrogen abundance, surface topography, and prevalence of shadowed regions, as well as solar illumination and direct to Earth communications as a function of time to develop a notional rover traverse plan that addresses both science and engineering requirements. We also present lessons-learned regarding lunar traverse path planning focusing on the critical nature of landing site selection, the influence of illumination patterns on traverse planning, the effects of performing shadowed rover operations, the influence of communications coverage on traverse plan development, and strategic planning to maximize rover lifetime and science at end of mission. Here we present a detailed traverse path scenario for a lunar polar volatiles rover mission and find that the particular site north of Haworth Crater studied here is suitable for further characterization of polar volatile deposits.

Published
2016

18. Lunar polar rover science operations: Lessons learned and mission architecture implications derived from the Mojave Volatiles Prospector (MVP) terrestrial field campaign

Author

Carol R. Stoker, Jennifer L. Heldmann, Mark Shirley, Amanda Cook, N. E. Button, David Lees, J. R. Skok, Linda Kobayashi, Matthew Deans, Richard C. Elphic, Jessica J. Marquez, Rusty Hunt, Darlene Lim, Ted L. Roush, Anthony Colaprete, Suniti Karunatillake, and John L. Bresina

Subjects
Atmospheric Science, 010504 meteorology & atmospheric sciences, Payload, Aerospace Engineering, Astronomy and Astrophysics, 01 natural sciences, Astrobiology, Geophysics, Space and Planetary Science, 0103 physical sciences, General Earth and Planetary Sciences, Environmental science, Polar, 010303 astronomy & astrophysics, Field campaign, 0105 earth and related environmental sciences
Abstract

The Mojave Volatiles Prospector (MVP) project is a science-driven field program with the goal of producing critical knowledge for conducting robotic exploration of the Moon. Specifically, MVP focuses on studying a lunar mission analog to characterize the form and distribution of lunar volatiles. Although lunar volatiles are known to be present near the poles of the Moon, the three dimensional distribution and physical characteristics of lunar polar volatiles are largely unknown. A landed mission with the ability to traverse the lunar surface is thus required to characterize the spatial distribution of lunar polar volatiles. NASA’s Resource Prospector (RP) mission is a lunar polar rover mission that will operate primarily in sunlit regions near a lunar pole with near-real time operations to characterize the vertical and horizontal distribution of volatiles. The MVP project was conducted as a field campaign relevant to the RP lunar mission to provide science, payload, and operational lessons learned to the development of a real-time, short-duration lunar polar volatiles prospecting mission. To achieve these goals, the MVP project conducted a simulated lunar rover mission to investigate the composition and distribution of surface and subsurface volatiles in a natural environment with an unknown volatile distribution within the Mojave Desert, improving our understanding of how to find, characterize, and access volatiles on the Moon.

Published
2016

19. Basaltic fissure types on Earth: Suitable analogs to evaluate the origins of volcanic terrains on the Moon and Mars?

Author

Jennifer L. Heldmann, Scott S. Hughes, Derek W. G. Sears, Shannon E. Kobs Nawotniak, Eric H. Christiansen, W. Brent Garry, Darlene S. S. Lim, Alexander Sehlke, and Richard C. Elphic

Subjects
Basalt, geography, Dike, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Geochemistry, Pyroclastic rock, Astronomy and Astrophysics, 01 natural sciences, Volcano, Impact crater, Space and Planetary Science, 0103 physical sciences, Rille, Rift zone, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences, Tharsis
Abstract

Basaltic eruptive fissures of the Great Rift and surroundings on the eastern Snake River Plain of Idaho, USA, and selected volcanic features in Hawai’i, Iceland and northern Africa were surveyed for their relevancy as planetary analogs. Evaluated during field investigations and in satellite imagery for structures, physiography, and geologic setting, fissures were categorized into four broad types: (1) simple, monogenetic fissures with obvious volcanic constructs or deposits, (2) monogenetic fissures now obscured by low shields or relatively large cones, (3) polygenetic volcanic rift zones with multiple vents and deposits, and (4) compound regional fissure systems or dike swarms that comprise major rift zones or large volcanic terrains. Using this classification as an initial base, we surveyed imagery of volcanic features for likely fissure vents in two major geologic settings on the Moon: floor-fractured craters (FFCs) and mare and cryptomare provinces. Two major regions on Mars, the volcanic plains around Alba Mons and the greater Tharsis region, were also surveyed for fissure types and volcanic associations of fissure-like features. The planetary surveys suggest that the proposed classification provides a suitable analog starting point to interpret structures associated with fissure systems on the Moon and Mars. With few exceptions, our survey indicates that each of the studied terrains exhibits a dominant fissure type. Type 1 fissures, most with pyroclastic deposits, prevail in lunar FFCs and mare-like regions; whereas type 2 fissures are ubiquitous in the Tharsis region of Mars and a few exist on the Moon as low shields. Type 3 volcanic rift zones are not common on either the Moon or Mars, although they might become evident in future work on chemically evolved terrains. Type 4 fissures are inferred in mare terrains, often represented as the extensions of major linear rille networks or rimae, with possibly complex dike swarms that were buried beneath voluminous mare basalt lava flows. Likewise, numerous flood lavas on Mars are possibly associated with now-obscured or difficult to define type 4 fissure systems.

Published
2020

20. Characterizing the hydroxyl observation of the LCROSS UV-visible spectrometer: Modeling of the impact plume

Author

Anthony Colaprete, Yasvanth Poondla, Jennifer L. Heldmann, Aayush Agrawal, Philip L. Varghese, David Goldstein, Sergio Tovar, Arnaud Mahieux, and Laurence M. Trafton

Subjects
Materials science, 010504 meteorology & atmospheric sciences, Spectrometer, Photodissociation, Mineralogy, Astronomy and Astrophysics, 01 natural sciences, Regolith, Plume, Impact crater, Space and Planetary Science, Desorption, 0103 physical sciences, Sublimation (phase transition), 010303 astronomy & astrophysics, Water vapor, 0105 earth and related environmental sciences
Abstract

Lunar Crater Observation and Sensing Satellite (LCROSS) impacted the Cabeus crater near the lunar South Pole on 9 October 2009 and generated an impact plume. The hydroxyl (OH) band strength observations obtained from the LCROSS mission are explained with the help of numerical modeling of the impact plume. We provide different models of OH production in the plume and conduct a parametric study to constrain the independent parameters of these models. In particular, detailed lofted grain heating, sublimation and photodissociation models are implemented along with models for H2O and OH production from the residual impact crater. Results show that the likely sources of observed OH are from a small amount of direct/abrasional OH desorption from regolith grains (~28 g) in the crater and from sublimation of water vapor ( O (800 kg)) from lofted regolith-imbued ice grains followed by photodissociation.

Published
2020

21. Modeling the effects of martian surface frost on ice table depth

Author

Christopher P. McKay, Jennifer L. Heldmann, and K.E. Williams

Subjects
geography, Ground frost, geography.geographical_feature_category, Frost heaving, Astronomy and Astrophysics, Atmospheric sciences, Snow, Arctic ice pack, Space and Planetary Science, Sea ice thickness, Cryosphere, Martian polar ice caps, Water vapor, Geology
Abstract

Ground ice has been observed in small fresh craters in the vicinity of the Viking 2 lander site (48°N, 134°E). To explain these observations, current models for ground ice invoke levels of atmospheric water of 20 precipitable micrometers – higher than observations. However, surface frost has been observed at the Viking 2 site and surface water frost and snow have been shown to have a stabilizing effect on Antarctic subsurface ice. A snow or frost cover provides a source of humidity that should reduce the water vapor gradient and hence retard the sublimation loss from subsurface ice. We have modeled this effect for the Viking 2 landing site with combined ground ice and surface frost models. Our model is driven by atmospheric output fields from the NASA Ames Mars General Circulation Model (MGCM). Our modeling results show that the inclusion of a thin seasonal frost layer, present for a duration similar to that observed by the Viking Lander 2, produces ice table depths that are significantly shallower than a model that omits surface frost. When a maximum frost albedo of 0.35 was permitted, seasonal frost is present in our model from Ls = 182° to Ls = 16°, resulting in an ice table depth of 64 cm – which is 24 cm shallower than the frost-free scenario. The computed ice table depth is only slightly sensitive to the assumed maximum frost albedo or thickness in the model.

Published
2015

22. Formation of the 'ponds' on asteroid (433) Eros by fluidization

Author

Livio L. Tornabene, Scott S. Hughes, Gordon R. Osinski, Derek W. G. Sears, and Jennifer L. Heldmann

Subjects
Impact crater, Space and Planetary Science, Asteroid, Asteroid belt, Astronomy and Astrophysics, Context (language use), Mars Exploration Program, Regolith, Water vapor, Geology, Phreatic, Astrobiology
Abstract

The “ponds” on asteroid (433) Eros are fine-grained deposits approximating flat (quasi-equipotential) surfaces with respect to local topographic depressions (e.g., craters) in spacecraft images. These ponds are discussed in the context of laboratory simulation experiments, crater-related ponded and pitted deposits observed on Mars and Vesta, terrestrial phreatic craters, and degassing features associated with eroded impact craters on Earth. While the details of formation of these features on Mars, Vesta and the Earth are thought to be different, they all include mechanisms that require the interactions between surface materials and volatiles (e.g., water vapor). Indeed, analogous features similar to the Eros ponds can be reproduced in the laboratory by the release of vapor (ice sublimation, water evaporation, or N2) through an unconsolidated regolith (independent of regolith composition). Eros is widely thought to be dry, but the discovery of exogenic water on Vesta, and recent arguments that subsurface water might be present in the inner asteroid belt suggest that endogenic water might also be present and serve as a source of the gases produced in the ponds. The amount of water required is comparable to the amount of water observed in little-metamorphosed ordinary chondrites (a few wt%). The primary morphologic characteristics of the Eros ponds can be explained in this model. The heat source for degassing could have been solar heating following transfer from a main belt orbit to a near Earth orbit. Although other hypotheses (e.g., electrostatic levitation, seismic shaking, and comminution of boulders) can account for most of the features of the ponds, recent observations regarding the role of volatiles on planetary surfaces, our laboratory experiments, and fluidization deposits on active comets suggests that degassing is a reasonable hypothesis to be considered and further tested for explaining the Eros ponds, and similar features on other bodies.

Published
2015

23. Solar Radiation and Air and Ground Temperature Relations in the Cold and Hyper-Arid Quartermain Mountains, McMurdo Dry Valleys of Antarctica

Author

Alfonso F. Davila, Caitlin Lapalme, Wayne H. Pollard, Denis Lacelle, Christopher P. McKay, Jennifer L. Heldmann, and Margarita M. Marinova

Subjects
Hydrology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Glacier, 010502 geochemistry & geophysics, Permafrost, Snow, 01 natural sciences, Arid, Arctic, Soil water, Table (landform), Meltwater, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

This study compares the relations between solar radiation and air and ground temperatures in the Quartermain Mountains of the McMurdo Dry Valleys of Antarctica with those in ice-free Victoria Land and Arctic Canada. The surface offset is near 0°C at all sites in the Quartermain Mountains and other sites in coastal Victoria Land, whereas the thermal offset is near 0°C at shallow ice table depths ( 0°C for at least a few hours. Soils in the PCZs experience water exchange through vapour diffusion, whereas soils in the NCZs contain features associated with liquid water activity, such as increased soil moisture and frozen ponds recharged by snow/glacier meltwater. Copyright © 2015 John Wiley & Sons, Ltd.

Published
2015

24. Real-time science operations to support a lunar polar volatiles rover mission

Author

Jennifer L. Heldmann, Anthony Colaprete, Kimberly Ennico, Margarita M. Marinova, Richard C. Elphic, Robert E. McMurray, Ted L. Roush, Carol R. Stoker, Gregory W. Mattes, E. Fritzler, and Stephanie Morse

Subjects
Atmospheric Science, Situation awareness, Payload, Computer science, Scientific visualization, Aerospace Engineering, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Astronomy and Astrophysics, In situ resource utilization, Regolith, Field (computer science), Concept of operations, Geophysics, Space and Planetary Science, Systems engineering, General Earth and Planetary Sciences, Research center, Remote sensing
Abstract

Future human exploration of the Moon will likely rely on in situ resource utilization (ISRU) to enable long duration lunar missions. Prior to utilizing ISRU on the Moon, the natural resources (in this case lunar volatiles) must be identified and characterized, and ISRU demonstrated on the lunar surface. To enable future uses of ISRU, NASA and the CSA are developing a lunar rover payload that can (1) locate near subsurface volatiles, (2) excavate and analyze samples of the volatile-bearing regolith, and (3) demonstrate the form, extractability and usefulness of the materials. Such investigations are important both for ISRU purposes and for understanding the scientific nature of these intriguing lunar volatile deposits. Temperature models and orbital data suggest near surface volatile concentrations may exist at briefly lit lunar polar locations outside persistently shadowed regions. A lunar rover could be remotely operated at some of these locations for the ∼ 2–14 days of expected sunlight at relatively low cost. Due to the limited operational time available, both science and rover operations decisions must be made in real time, requiring immediate situational awareness, data analysis, and decision support tools. Given these constraints, such a mission requires a new concept of operations. In this paper we outline the results and lessons learned from an analog field campaign in July 2012 which tested operations for a lunar polar rover concept. A rover was operated in the analog environment of Hawaii by an off-site Flight Control Center, a rover navigation center in Canada, a Science Backroom at NASA Ames Research Center in California, and support teams at NASA Johnson Space Center in Texas and NASA Kennedy Space Center in Florida. We find that this type of mission requires highly efficient, real time, remotely operated rover operations to enable low cost, scientifically relevant exploration of the distribution and nature of lunar polar volatiles. The field demonstration illustrated the need for science operations personnel in constant communications with the flight mission operators and the Science Backroom to provide immediate and continual science support and validation throughout the mission. Specific data analysis tools are also required to enable immediate data monitoring, visualization, and decision making. The field campaign demonstrated that this novel methodology of real-time science operations is possible and applicable to providing important new insights regarding lunar polar volatiles for both science and exploration.

Published
2015

25. Simulated real-time lunar volatiles prospecting with a rover-borne neutron spectrometer

Author

Stephanie Morse, Robert E. McMurray, Anthony Colaprete, Richard C. Elphic, Carol R. Stoker, Trey Smith, Margarita M. Marinova, Jennifer L. Heldmann, E. Fritzler, Matthew Deans, and Ted L. Roush

Subjects
Atmospheric Science, Decision support system, Spectrometer, Aerospace Engineering, Astronomy and Astrophysics, In situ resource utilization, Geophysics, Resource (project management), Space and Planetary Science, General Earth and Planetary Sciences, Prospecting, Environmental science, Water ice, Short duration, Remote sensing
Abstract

In situ resource utilization (ISRU) may one day enable long duration lunar missions. But the efficacy of such an approach greatly depends on (1) physical and chemical makeup of the resource, and (2) the logistical cost of exploiting the resource. Establishing these key strategic factors requires prospecting: the capability of locating and characterizing potential resources. There is already considerable evidence from orbital and impact missions that the lunar poles harbor plausibly rich reservoirs of volatiles. The next step is to land on the Moon and assess the nature, “ore-grade”, and extractability of water ice and other materials. In support of this next step, a mission simulation was carried out on the island of Hawai’i in July of 2012. A robotic rover, provided by the Canadian Space Agency, carried several NASA ISRU-supporting instruments in a field test to address how such a mission might be carried out. This exercise was meant to test the ability to (a) locate and characterize volatiles, (b) acquire subsurface samples in a volatile-rich location, and (c) analyze the form and composition of the volatiles to determine their utility. This paper describes the successful demonstration of neutron spectroscopy as a prospecting and decision support system to locate and evaluate potential ISRU targets in the field exercise.

Published
2015

26. A record of igneous evolution in Elysium, a major martian volcanic province

Author

T. Judice, D. A. Susko, Agnes Cousin, J. R. Skok, Jennifer L. Heldmann, G. R. L. Kodikara, Suniti Karunatillake, James J. Wray, Institut de recherche en astrophysique et planétologie (IRAP), Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), and Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Centre National de la Recherche Scientifique (CNRS)

Subjects
Martian, geography, Multidisciplinary, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Geochemistry, Crust, 01 natural sciences, Article, Elysium, Astrobiology, Igneous rock, Impact crater, Volcano, Lava field, [SDU]Sciences of the Universe [physics], 0103 physical sciences, Magmatism, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences
Abstract

A major knowledge gap exists on how eruptive compositions of a single martian volcanic province change over time. Here we seek to fill that gap by assessing the compositional evolution of Elysium, a major martian volcanic province. A unique geochemical signature overlaps with the southeastern flows of this volcano, which provides the context for this study of variability of martian magmatism. The southeastern lava fields of Elysium Planitia show distinct chemistry in the shallow subsurface (down to several decimeters) relative to the rest of the martian mid-to-low latitudes (average crust) and flows in northwest Elysium. By impact crater counting chronology we estimated the age of the southeastern province to be 0.85 ± 0.08 Ga younger than the northwestern fields. This study of the geochemical and temporal differences between the NW and SE Elysium lava fields is the first to demonstrate compositional variation within a single volcanic province on Mars. We interpret the geochemical and temporal differences between the SE and NW lava fields to be consistent with primary magmatic processes, such as mantle heterogeneity or change in depth of melt formation within the martian mantle due to crustal loading.

Published
2017
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28. Reaching 1 m Deep on Mars: The Icebreaker Drill

Author

M. Hedlund, B. Mellerowicz, Carol R. Stoker, Kris Zacny, C. P. McKay, Alfonso F. Davila, Brian Glass, A. Dave, Jack Craft, Jennifer L. Heldmann, Gale Paulsen, Nathalie A. Cabrol, and Margarita M. Marinova

Subjects
Committee on Space Research, Drill, Planetary protection, Ice, Mars, In situ resource utilization, Mars Exploration Program, Space Flight, Agricultural and Biological Sciences (miscellaneous), Scientific analysis, Space and Planetary Science, Environmental science, Water ice, Delivery system, Remote sensing, Marine engineering
Abstract

The future exploration of Mars will require access to the subsurface, along with acquisition of samples for scientific analysis and ground-truthing of water ice and mineral reserves for in situ resource utilization. The Icebreaker drill is an integral part of the Icebreaker mission concept to search for life in ice-rich regions on Mars. Since the mission targets Mars Special Regions as defined by the Committee on Space Research (COSPAR), the drill has to meet the appropriate cleanliness standards as requested by NASA's Planetary Protection Office. In addition, the Icebreaker mission carries life-detection instruments; and in turn, the drill and sample delivery system have to meet stringent contamination requirements to prevent false positives. This paper reports on the development and testing of the Icebreaker drill, a 1 m class rotary-percussive drill and triple redundant sample delivery system. The drill acquires subsurface samples in short, approximately 10 cm bites, which makes the sampling system robust and prevents thawing and phase changes in the target materials. Autonomous drilling, sample acquisition, and sample transfer have been successfully demonstrated in Mars analog environments in the Arctic and the Antarctic Dry Valleys, as well as in a Mars environmental chamber. In all environments, the drill has been shown to perform at the "1-1-100-100" level; that is, it drilled to 1 m depth in approximately 1 hour with less than 100 N weight on bit and approximately 100 W of power. The drilled substrate varied and included pure ice, ice-rich regolith with and without rocks and with and without 2% perchlorate, and whole rocks. The drill is currently at a Technology Readiness Level (TRL) of 5. The next-generation Icebreaker drill weighs 10 kg, which is representative of the flightlike model at TRL 5/6.

Published
2013

29. Polygonal ground in the McMurdo Dry Valleys of Antarctica and its relationship to ice-table depth and the recent Antarctic climate history

Author

Michael T. Mellon, Christopher P. McKay, and Jennifer L. Heldmann

Subjects
geography, geography.geographical_feature_category, Landform, Geology, Mars Exploration Program, Oceanography, Permafrost, Latitude, Remote sensing (archaeology), Polygon, Table (landform), Geomorphology, Ecology, Evolution, Behavior and Systematics, Patterned ground
Abstract

The occurrence of dry permafrost overlying ice-rich permafrost is unique to the Antarctic Dry Valleys on Earth and to the high latitudes of Mars. The stability and distribution of this ice are poorly understood and fundamental to understanding the Antarctic climate as far back as a few million years. Polygonal patterned ground is nearly ubiquitous in these regions and is integrally linked to the history of the icy permafrost and climate. We examined the morphology of polygonal ground in Beacon Valley and the Beacon Heights region of the Antarctic Dry Valleys, and show that polygon size is correlated with ice-table depth (the boundary between dry and ice-rich permafrost). A numerical model of seasonal stress in permafrost shows that the ice-table depth is a dominant factor. Remote sensing and field observations of polygon size are therefore important tools for investigating subsurface ice. Polygons are long-lived landforms and observed characteristics indicate no major fluctuations in the ice-table depth during their development. We conclude that the Beacon Valley and Beacon Heights polygons have developed for at least 104years to achieve their present mature-stage morphology and that the ice-table depth has been stable for a similar length of time.

Published
2013

30. Excess ground ice of condensation–diffusion origin in University Valley, Dry Valleys of Antarctica: Evidence from isotope geochemistry and numerical modeling

Author

David A. Fisher, Alfonso F. Davila, Denis Lacelle, Jennifer L. Heldmann, Regina DeWitt, Wayne H. Pollard, Christopher P. McKay, and Margarita M. Marinova

Subjects
geography, geography.geographical_feature_category, Ice stream, Earth science, Geochemistry, Antarctic sea ice, Arctic ice pack, Ice core, Geochemistry and Petrology, Melt pond, Ice age, Cryosphere, Ice sheet, Geology
Abstract

This study investigates the origin and age of ground ice in the uppermost 1 m of permafrost in University Valley, one of the upper valleys in the McMurdo Dry Valleys of Antarctica. In contrast to other regions in the MDV, mean daily air and soil temperatures at the coring sites are always below 0 °C, which allows for unique cryogenic processes to occur. In the two cores that were analyzed, excess ground ice was measured throughout, ranging between 23% and 85%. Isotope geochemical trends in the ice-rich permafrost indicate that the ground in Core 5 (65 cm long) and the uppermost 52 cm of Core 7 originated from condensation–diffusion of water vapor; whereas the ground ice between 57–90 cm in Core 7 originated from freezing of liquid water. Using numerical modeling, we show that the excess ground ice of condensation–diffusion origin formed by the long-term thermal contraction–expansion of the cryotic sediments, which allowed for the ice content to exceed pore-filling capacity. Absolute age estimates of the sandy-loam sediments based on Optically Stimulated Luminescence dating indicate that soils have been accreting at the site for at least the last 170 ± 36 ka years, and this places an upper limit to the age of the ground ice. Absolute soil ages allowed us to link the change in ground ice origin in Core 7, which took place around 152 ± 12 ka years, with shifts in climate conditions since marine isotope stage 5e interglacial period. Our findings offer a new process of ground ice emplacement in sediments in cold–dry environments and allow an alternative explanation regarding the enigmatic origin of excess ground ice identified by Mars Odyssey and Phoenix in the northern martian plain, which is that overfilled pore ice can form by vapor deposition and repeated thermal cycling without the presence of melt water.

Published
2013

31. Desert Research and Technology Studies (DRATS) 2010 science operations: Operational approaches and lessons learned for managing science during human planetary surface missions

Author

Kip V. Hodges, Carolyn M. Tewksbury-Christle, Catherine Juranek, Gary E. Lofgren, B. A. Adams, Susan M. Lederer, Sarah K. Noble, B. D. Monteleone, José M. Hurtado, D. W. Ming, James W. Rice, Adrian J. Brown, Brian M. Hynek, David A. Kring, C. a. Evans, Kelsey Young, A. Yingst, Lisa May, Barbara A. Cohen, C. M. Fortezzo, Barbara J. Tewksbury, Friedrich Hörz, Jennifer L. Heldmann, Brent Garry, Jonathan Meyer, D. Archer, Peter J. Isaacson, James A. Skinner, K. K. Klaus, Christopher D. Condit, John Gruener, Alicia Vaughan, Caroline Morisset, Dean Eppler, Margarita M. Marinova, William Carey, John Schutt, Greg Baiden, E. B. Rampe, Trevor G. Graff, and Nina Lanza

Subjects
Engineering, Traverse, Operations research, SIMPLE (military communications protocol), Process (engineering), business.industry, media_common.quotation_subject, Crew, Aerospace Engineering, Exploration of Mars, Field (computer science), Aeronautics, Quality (business), Baseline (configuration management), business, media_common
Abstract

Desert Research and Technology Studies (Desert RATS) is a multi-year series of hardware and operations tests carried out annually in the high desert of Arizona on the San Francisco Volcanic Field. These activities are designed to exercise planetary surface hardware and operations in conditions where long-distance, multi-day roving is achievable, and they allow NASA to evaluate different mission concepts and approaches in an environment less costly and more forgiving than space.The results from the RATS tests allows election of potential operational approaches to planetary surface exploration prior to making commitments to specific flight and mission hardware development. In previous RATS operations, the Science Support Room has operated largely in an advisory role, an approach that was driven by the need to provide a loose science mission framework that would underpin the engineering tests. However, the extensive nature of the traverse operations for 2010 expanded the role of the science operations and tested specific operational approaches. Science mission operations approaches from the Apollo and Mars-Phoenix missions were merged to become the baseline for this test. Six days of traverse operations were conducted during each week of the 2-week test, with three traverse days each week conducted with voice and data communications continuously available, and three traverse days conducted with only two 1-hour communications periods per day. Within this framework, the team evaluated integrated science operations management using real-time, tactical science operations to oversee daily crew activities, and strategic level evaluations of science data and daily traverse results during a post-traverse planning shift. During continuous communications, both tactical and strategic teams were employed. On days when communications were reduced to only two communications periods per day, only a strategic team was employed. The Science Operations Team found that, if communications are good and down-linking of science data is ensured, high quality science returns is possible regardless of communications. What is absent from reduced communications is the scientific interaction between the crew on the planet and the scientists on the ground. These scientific interactions were a critical part of the science process and significantly improved mission science return over reduced communications conditions. The test also showed that the quality of science return is not measurable by simple numerical quantities but is, in fact, based on strongly non-quantifiable factors, such as the interactions between the crew and the Science Operations Teams. Although the metric evaluation data suggested some trends, there was not sufficient granularity in the data or specificity in the metrics to allow those trends to be understood on numerical data alone.

Published
2013

32. The high elevation Dry Valleys in Antarctica as analog sites for subsurface ice on Mars

Author

C. P. McKay, Dale T. Andersen, Alfonso F. Davila, Jennifer L. Heldmann, Margarita M. Marinova, Denis Lacelle, K.E. Williams, and Wayne H. Pollard

Subjects
Drift ice, geography, geography.geographical_feature_category, Ice stream, Astronomy and Astrophysics, Antarctic sea ice, Arctic ice pack, Space and Planetary Science, Sea ice, Cryosphere, Martian polar ice caps, Ice sheet, Geomorphology, Geology
Abstract

The high elevation valleys of the McMurdo Dry Valleys of Antarctica are the only locations on Earth known to contain dry permafrost. The Dry Valleys are a hyper-arid polar desert environment and above 1500 m elevation, air temperatures do not exceed 0 °C and thus, similarly to Mars, liquid water is largely absent and instead the hydrologic cycle is dominated by frozen ice and vapor phase processes such as sublimation. These conditions make the high elevation Dry Valleys a key Mars analog location where periglacial processes and geomorphic features, and their use as a diagnostic for subsurface ice, can be studied in situ. Two valleys in the upper Dry Valleys show a diversity of subsurface ice; University Valley is dominated by dry permafrost overlying ice-cemented to ice-bonded ground and nearby middle Beacon Valley is dominated by massive ground ice. In both cases the ice is 10–60 cm below the surface. Here we compare the surface features in these two valleys to assess any correlation with the nature of the subsurface ice and compare these features to similar features seen at the Phoenix landing site on Mars. We conclude that while surface features may be indicative of ground ice, no specific correlations are possible and more direct methods are required to determine the nature of subsurface ice on Mars.

Published
2013

33. The Icebreaker Life Mission to Mars: A Search for Biomolecular Evidence for Life

Author

Gale Paulsen, Wayne H. Pollard, Denis Lacelle, Michael H. Hecht, Victor Parro, Pete Smith, Alfonso F. Davila, Dale T. Andersen, A. Dave, Richard C. Quinn, Brian Glass, Kris Zacny, Margarita M. Marinova, Alberto G. Fairén, Carol R. Stoker, Christopher P. McKay, and Jennifer L. Heldmann

Subjects
Perchlorates, Extraterrestrial Environment, biology, Planetary protection, United States National Aeronautics and Space Administration, Ice, Mars, Water, Mars Exploration Program, biology.organism_classification, Life on Mars, Agricultural and Biological Sciences (miscellaneous), United States, Astrobiology, Atmosphere, Soil, Life, Space and Planetary Science, Planet, Extraterrestrial life, Exobiology, Environmental science, Phoenix, Energy source
Abstract

The search for evidence of life on Mars is the primary motivation for the exploration of that planet. The results from previous missions, and the Phoenix mission in particular, indicate that the ice-cemented ground in the north polar plains is likely to be the most recently habitable place that is currently known on Mars. The near-surface ice likely provided adequate water activity during periods of high obliquity, ≈ 5 Myr ago. Carbon dioxide and nitrogen are present in the atmosphere, and nitrates may be present in the soil. Perchlorate in the soil together with iron in basaltic rock provides a possible energy source for life. Furthermore, the presence of organics must once again be considered, as the results of the Viking GCMS are now suspect given the discovery of the thermally reactive perchlorate. Ground ice may provide a way to preserve organic molecules for extended periods of time, especially organic biomarkers. The Mars Icebreaker Life mission focuses on the following science goals: (1) Search for specific biomolecules that would be conclusive evidence of life. (2) Perform a general search for organic molecules in the ground ice. (3) Determine the processes of ground ice formation and the role of liquid water. (4) Understand the mechanical properties of the martian polar ice-cemented soil. (5) Assess the recent habitability of the environment with respect to required elements to support life, energy sources, and possible toxic elements. (6) Compare the elemental composition of the northern plains with midlatitude sites. The Icebreaker Life payload has been designed around the Phoenix spacecraft and is targeted to a site near the Phoenix landing site. However, the Icebreaker payload could be supported on other Mars landing systems. Preliminary studies of the SpaceX Dragon lander show that it could support the Icebreaker payload for a landing either at the Phoenix site or at midlatitudes. Duplicate samples could be cached as a target for possible return by a Mars Sample Return mission. If the samples were shown to contain organic biomarkers, interest in returning them to Earth would be high.

Published
2013

34. Distribution of depth to ice-cemented soils in the high-elevation Quartermain Mountains, McMurdo Dry Valleys, Antarctica

Author

Gale Paulsen, Kris Zacny, Margarita M. Marinova, W. Andrew Jackson, Alfonso F. Davila, Denis Lacelle, Dale T. Andersen, Christopher P. McKay, Wayne H. Pollard, and Jennifer L. Heldmann

Subjects
geography, geography.geographical_feature_category, Climate change, Geology, Glacier, Albedo, Oceanography, Snow, Head (geology), U-shaped valley, High elevation, Soil water, Geomorphology, Ecology, Evolution, Behavior and Systematics
Abstract

We report on 475 measurements of depth to ice-cemented ground in four high-elevation valleys of the Quartermain Mountains, McMurdo Dry Valleys, Antarctica. These valleys have pervasive ice-cemented ground, and the depth to ice-cemented ground and the ice composition may be indicators of climate change. In University Valley, the measured depth to ice-cemented ground ranges from 0–98 cm. There is an overall trend of increasing depth to ice-cemented ground with distance from a small glacier at the head of the valley, with a slope of 32 cm depth per kilometre along the valley floor. For Farnell Valley, the depth to ice-cemented ground is roughly constant (c. 30 cm) in the upper and central parts of the valley, but increases sharply as the valley descends into Beacon Valley. The two valleys north of University Valley also have extensive ice-cemented ground, with depths of 20–40 cm, but exhibit no clear patterns of ice depth with location. For all valleys there is a tendency for the variability in depth to ice-cemented ground at a site to increase with increasing depth to ice. Snow recurrence, solar insolation, and surface albedo may all be factors that cause site to site variations in these valleys.

Published
2013

35. LCROSS (Lunar Crater Observation and Sensing Satellite) Observation Campaign: Strategies, Implementation, and Lessons Learned

Author

Ray W. Russell, Duk Hang Lee, Young-Jun Choi, Eliot F. Young, J. Jedadiah Rembold, Anthony C. Matulonis, Lawrence Ong, Imke de Pater, Peter Backus, Michael Long, Ryosuke Nakamura, Stephen A. Gregory, Michael S. P. Kelley, Samantha Blair, Vanessa P. Bailey, David E. Harker, David Goldstein, James R. Forster, Paul G. Lucey, Jun Ihi Watanabe, Richard M. McDermid, Shawn Callahan, J. Duane Gibson, R. F. Ackermann, Katherine C. Roth, John T. Rayner, Hong Kyu Moon, Steven P. James, Faith Vilas, Anthony Colaprete, Toshihiko Kadono, Junichi Haruyama, Mark A. Skinner, Jennifer L. Heldmann, Naruhisa Takatoh, Reiko Furusho, Marc W. Buie, G. R. Harp, William J. Welch, Ryan T. Hamilton, Eon Chang Sung, Chadwick J. Trujillo, Nancy J. Chanover, Seiji Sugita, Keith Marach, Thomas R. Geballe, Jesse G. Ball, Morag Ann Hastie, C. Miller, Kirk Crawford, Tomohiko Sekiguchi, Hirotomo Noda, Hong Suh Yim, Michael A. DiSanti, Charles E. Woodward, Brian D. Walls, P. M. Hinz, William C. Barott, R. J. McMillan, Hideyo Kawakita, Russell DeHart, Richard J. Rudy, Diane H. Wooden, N. Okamura, William Ryan, Taiga Hamura, Tetsuharu Fuse, Andrew W. Stephens, Scott M. Taylor, Eileen V. Ryan, Mitsuru Sôma, David Acton, Vidhya Vaitheeswaran, D. L. Kim, Yasuhito Sekine, Dolores M. Coulson, Robert M. Suggs, Peng K. Hong, David J. Gutierrez, Dallan Porter, Kosuke Kurosawa, Al Conrad, Alex D. Storrs, Hiroshi Terada, Yutaka Hayano, Jeffery J. Puschell, and Jill Tarter

Subjects
Satellite observation, 010504 meteorology & atmospheric sciences, Spacecraft, business.industry, Astronomy and Astrophysics, 01 natural sciences, Astrobiology, Planetary science, Impact crater, Space and Planetary Science, 0103 physical sciences, Launch vehicle, Satellite, business, Ejecta, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences, Remote sensing
Abstract

著者人数: 87名, Accepted: 2011-02-08, 資料番号: SA1004099000

Published
2012

36. An Overview of the Lunar Crater Observation and Sensing Satellite (LCROSS)

Author

Jennifer L. Heldmann, Anthony Colaprete, Kimberly Ennico, and Richard C. Elphic

Subjects
Lunar water, Lunar craters, Planetary science, Impact crater, Space and Planetary Science, Ejecta blanket, Astronomy and Astrophysics, Ejecta, Regolith, Geology, Transient lunar phenomenon, Astrobiology
Abstract

The Lunar Crater Observation Sensing Satellite (LCROSS), an accompanying payload to the Lunar Reconnaissance Orbiter (LRO) mission (Vondrak et al. 2010), was launched with LRO on 18 June 2009. The principle goal of the LCROSS mission was to shed light on the nature of the materials contained within permanently shadowed lunar craters. These Permanently Shadowed Regions (PSRs) are of considerable interest due to the very low temperatures

Published
2012

37. Formation and evolution of buried snowpack deposits in Pearse Valley, Antarctica, and implications for Mars

Author

Margarita M. Marinova, C. P. McKay, Denis Lacelle, K.E. Williams, Dale T. Andersen, Jennifer L. Heldmann, Wayne H. Pollard, and Alfonso F. Davila

Subjects
Martian, Arctic, Geology, Mars Exploration Program, Snowpack, Oceanography, Snow, Geomorphology, Ecology, Evolution, Behavior and Systematics, Polar desert
Abstract

Buried snowpack deposits are found within the McMurdo Dry Valleys of Antarctica, which offers the opportunity to study these layered structures of sand and ice within a polar desert environment. Four discrete buried snowpacks are studied within Pearse Valley, Antarctica, through in situ observations, sample analyses, O-H isotope measurements and numerical modelling of snowpack stability and evolution. The buried snowpack deposits evolve throughout the year and undergo deposition, melt, refreeze, and sublimation. We demonstrate how the deposition and subsequent burial of snow can preserve the snowpacks in the Dry Valleys. The modelled lifetimes of the buried snowpacks are dependent upon subsurface stratigraphy but are typically less than one year if the lag thickness is less than c. 7 cm and snow thickness is less than c. 10 cm, indicating that some of the Antarctic buried snowpacks form annually. Buried snowpacks in the Antarctic polar desert may serve as analogues for similar deposits on Mars and may be applicable to observations of the north polar erg, buried ice at the Mars Phoenix landing site, and observations of buried ice throughout the martian Arctic. Numerical modelling suggests that seasonal snows and subsequent burial are not required to preserve the snow and ice on Mars.

Published
2012

38. Physics of a Thick Seasonal Snowpack with Possible Implications for Snow Algae

Author

Adrienne Dove, Christopher P. McKay, Jennifer L. Heldmann, and Owen B. Toon

Subjects
010506 paleontology, Global and Planetary Change, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Moisture, Albedo, Snowpack, Snow, 01 natural sciences, Algal bloom, Volcano, Liquid water content, Climatology, Surface runoff, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

Instrumentation to study snowpack in situ was deployed in Lassen Volcanic National Park (LVNP), California, in an area of deep seasonal snow accumulation and known snow algal bloom recurrence. Included in the instrumentation were 11 temperature sensors, evenly spaced up to 2 m above the ground, which provided (1) temperature data within the snowpack when buried, and (2) estimates of snowpack height during accumulation and ablation periods. Beginning in April, moisture sensors measured a strong increase of snowpack liquid water content to greater than 15% by volume; this high melt content is usually coincident with the start of runoff from the snowpack. Snow depth profiles showed a rapid ablation of the final 2 m of the snowpack over about 23 days beginning in late June. SNTHERM numerical modeling confirmed that solar radiation was the dominant energy term throughout the melt season. By modeling a variety of snowpack parameters, such as albedo and initial snow density, we determined that the date ...

Published
2012

39. Stability of massive ground ice bodies in University Valley, McMurdo Dry Valleys of Antarctica: Using stable O–H isotope as tracers of sublimation in hyper-arid regions

Author

Alfonso F. Davila, Dale T. Andersen, Denis Lacelle, Jennifer L. Heldmann, Wayne H. Pollard, Margarita M. Marinova, and Christopher P. McKay

Subjects
geography, geography.geographical_feature_category, Ice stream, Blue ice, Glacier, Glacier morphology, Arctic ice pack, Geophysics, Ice core, Sea ice growth processes, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Cryosphere, Geomorphology, Geology
Abstract

To date, studies of the stability of subsurface ice in the McMurdo Dry Valleys of Antarctica have been mainly based on climate-based vapor diffusion models. In University Valley (1800 m), a small glacier is found at the base of the head of the valley, and adjacent to the glacier, a buried body of massive ice was uncovered beneath 20–40 cm of loose cryotic sediments and sandstone boulders. This study assesses the origin and stability of the buried body of massive ice by measuring the geochemistry and stable O–H isotope composition of the ice and applies a sublimation and molecular diffusion model that accounts for the observed trends. The results indicate that the buried massive ice body represents an extension of the adjacent glacier that was buried by a rock avalanche during a cold climate period. The contrasting δ 18 O profiles and regression slope values between the uppermost 6 cm of the buried massive ice (upward convex δ 18 O profile and S D-18O = 5.1) and that below it (progressive increase in δ 18 O and S D-18O = 6.4) suggest independent post-depositional processes affected the isotope composition of the ice. The upward convex δ 18 O profile in the uppermost 6 cm is consistent with the ice undergoing sublimation. Using a sublimation and molecular diffusion model, and assuming that diffusion occurred through solid ice, the sublimation rate needed to fit the measured δ 18 O profile is 0.2 ⋅ 10 − 3 mm yr − 1 , a value that is more similar to net ice removal rates derived from 3 He data from cobbles in Beacon Valley till (7.0 ⋅ 10 − 3 mm yr − 1 ) than sublimation rates computed based on current climate (0.1–0.2 mm yr −1 ). We suggest that the climate-based sublimation rates are offset due to potential ice recharge mechanisms or to missing parameters, particularly the nature and thermo-physical properties of the overlying sediments (i.e., temperature, humidity, pore structure and ice content, grain size).

Published
2011

40. Possible liquid water origin for Atacama Desert mudflow and recent gully deposits on Mars

Author

Catharine A. Conley, Lauren E. Fletcher, Janice L. Bishop, Jennifer L. Heldmann, Adrian J. Brown, and Christopher P. McKay

Subjects
Mineral hydration, Space and Planetary Science, Water flow, Mudflow, Sorting (sediment), Geochemistry, Astronomy and Astrophysics, Mars Exploration Program, Albedo, Arid, Debris, Geology
Abstract

Evidence of recent gully activity on Mars has been reported based on the formation of new light toned deposits within the past decade, the origin of which remains controversial. Analogous recent light toned gully features have formed by liquid water activity in the Atacama Desert on Earth. These terrestrial deposits leave no mineralogical trace of water activity but rather show an albedo difference due to particle size sorting within a fine-grained mudflow. Therefore, spectral differences indicating varying mineralogy between a recent gully deposit and the surrounding terrain may not be the most relevant criteria for detecting water flow in arid environments. Instead, variation in particle size between the deposit and surrounding terrain is a possible discriminator to identify a water-based flow. We show that the Atacama deposit is similar to the observed Mars gully deposits, and both are consistent with liquid water activity. The light-toned Mars gully deposits could have formed from dry debris flows, but a liquid water origin cannot be ruled out because not all liquid water flows leave hydrated minerals behind on the surface. Therefore, the Mars deposits could be remnant mudflows that formed on Mars within the last decade.

Published
2010

41. Ancient melting of mid-latitude snowpacks on Mars as a water source for gullies

Author

Jennifer L. Heldmann, K. E. Williams, Michael T. Mellon, and Owen B. Toon

Subjects
Meteorology, Space and Planetary Science, Middle latitudes, Snowmelt, Astronomy and Astrophysics, Mars Exploration Program, Snowpack, Atmospheric sciences, Meltwater, Snow, Surface runoff, Geology, Latitude
Abstract

We hypothesize that during past epochs of high obliquity seasonal snowfields at mid-latitudes melted to produce springtime sediment-rich surface flows resulting in gully formation. Significant seasonal mid-latitude snowfall does not occur on Mars today. General Circulation Model (GCM) results, however, suggest that under past climate conditions there may have been centimeters of seasonal mid-latitude snowfall [Mischna, M.A., Richardson, M.I., Wilson, R.J., McCleese, D.J., 2003. J. Geophys. Res. Planets 108, doi:10.1029/2003JE002051 . 5062]. Gully locations have been tabulated by several researchers (e.g. [Heldmann, J.L., Mellon, M.T., 2004. Icarus 168, 285–304; Heldmann, J.L., Carlsson, E., Johansson, H., Mellon, M.T., Toon, O.B., 2007. Icarus 188, 324–344; Malin, M.C., Edgett, K.S., 2000. Science 288, 2330–2335]) and found to correspond to mid-latitude bands. A natural question is whether the latitudinal bands where the gullies are located correspond to areas where the ancient snowfalls may have melted, producing runoff which may have incised gullies. In this study we model thin snowpacks with thicknesses similar to those predicted by [Mischna, M.A., Richardson, M.I., Wilson, R.J., McCleese, D.J., 2003. J. Geophys. Res. Planets 108, doi:10.1029/2003JE002051 . 5062]. We model these snowpacks under past climate regimes in order to determine whether snowmelt runoff could have occurred, and whether significant amounts of warm soil ( T > 273 K ) existed on both poleward and equatorward slopes in the regions where gullies exist. Both warm soil and water amounts are modeled because soil and water may have mixed to form a sediment-rich flow. We begin by applying the snowpack model of Williams et al. [Williams, K.E., Toon, O.B., Heldmann, J.E., Mellon, M., 2008. Icarus 196, 565–577] to past climate regimes characterized by obliquities of 35° (600 ka before present) and 45° (5.5 ma before present), and to all latitudes between 70° N and 70° S. We find that the regions containing significant snowmelt runoff correspond to the regions identified by Heldmann and Mellon [Heldmann, J.L., Mellon, M.T., 2004. Icarus 168, 285–304], Heldmann et al. [Heldmann, J.L., Carlsson, E., Johansson, H., Mellon, M.T., Toon, O.B., 2007. Icarus 188, 324–344] and Malin and Edgett [Malin, M.C., Edgett, K.S., 2000. Science 288, 2330–2335] as containing large numbers of gullies. We find that the snowmelt runoff (>1 mm, with equivalent rainfall rates of 0.25 mm/h) and warm soil (>1 cm depth) would have occurred on slopes within the gullied latitudinal bands. The snowfall amounts modeled are predicted to be seasonal [Mischna, M.A., Richardson, M.I., Wilson, R.J., McCleese, D.J., 2003. J. Geophys. Res. Planets 108, doi:10.1029/2003JE002051 . 5062], and our modeling finds that under the previous climate regimes there would have been meltwater present on the slopes in question for brief periods of time, on the order of days, each year. Our model provides a simple explanation for the latitudinal distribution of the gullies, and also suggests that the gullies date to times when water migrated away from the present poles to the mid-latitudes.

Published
2009

42. The Subsurface Geology of Río Tinto: Material Examined During a Simulated Mars Drilling Mission for the Mars Astrobiology Research and Technology Experiment (MARTE)

Author

Howard Cannon, Brad Sutter, Olga Prieto-Ballesteros, Melissa Battler, John Schutt, Mary Sue Bell, Jennifer L. Heldmann, Javier Gómez-Elvira, Carol R. Stoker, and Jesús Martínez-Frías

Subjects
Geologic Sediments, Geological Phenomena, Technology, Drilling core, Remote mineralogical analysis, Drill, Research, Borehole, Mars, Drilling, Sampling (statistics), Río Tinto, Mars Exploration Program, Subsurface geology, Life on Mars, Iron oxides, Agricultural and Biological Sciences (miscellaneous), Astrobiology, Geological analysis, Spain, Space and Planetary Science, Exobiology, Space Simulation, Geology
Abstract

9 páginas, 4 figuras., The 2005 Mars Astrobiology Research and Technology Experiment (MARTE) project conducted a simulated 1-month Mars drilling mission in the Río Tinto district, Spain. Dry robotic drilling, core sampling, and biological and geological analytical technologies were collectively tested for the first time for potential use on Mars. Drilling and subsurface sampling and analytical technologies are being explored for Mars because the subsurface is the most likely place to find life on Mars. The objectives of this work are to describe drilling, sampling, and analytical procedures; present the geological analysis of core and borehole material; and examine lessons learned from the drilling simulation. Drilling occurred at an undisclosed location, causing the science team to rely only on mission data for geological and biological interpretations. Core and borehole imaging was used for micromorphological analysis of rock, targeting rock for biological analysis, and making decisions regarding the next day's drilling operations. Drilling reached 606 cm depth into poorly consolidated gossan that allowed only 35% of core recovery and contributed to borehole wall failure during drilling. Core material containing any indication of biology was sampled and analyzed in more detail for its confirmation. Despite the poorly consolidated nature of the subsurface gossan, dry drilling was able to retrieve useful core material for geological and biological analysis. Lessons learned from this drilling simulation can guide the development of dry drilling and subsurface geological and biological analytical technologies for future Mars drilling missions.

Published
2008

43. Stability of mid-latitude snowpacks on Mars

Author

Owen B. Toon, K. E. Williams, Michael T. Mellon, Christopher P. McKay, and Jennifer L. Heldmann

Subjects
Martian, geography, geography.geographical_feature_category, Astronomy and Astrophysics, Mars Exploration Program, Albedo, Snowpack, Snow, Atmospheric sciences, Latitude, Space and Planetary Science, Environmental science, Ice sheet, Meltwater
Abstract

Christensen [2003. Nature 422, 45–48] suggested that runoff from melting snowpacks on martian slopes might be responsible for carving gullies. He also suggested that snowpacks currently exist on Mars, for example on the walls of Dao Valles (approximately 33° S). Such snowpacks were presumably formed during the last obliquity cycle, which occurred about 70,000 years ago. In this paper we investigate a specific scenario under conditions we believe are favorable for snowpack melting. We model the rate at which a snowpack located at 33° S on a poleward-facing slope sublimates and melts on Mars, as well as the temperature profile within the snowpack. Our model includes the energy and mass balance of a snowpack experiencing diurnal variations in insolation. Our results indicate that a dirty snowpack would quickly sublimate and melt under current martian climate conditions. For example a 1 m thick dusty snowpack of moderate density (550 kg/m3) and albedo (0.39) would sublimate in less than two seasons, producing a small amount of meltwater runoff. Similarly, a cleaner snowpack (albedo 0.53) would disappear in less than 9 seasons. These results suggest that the putative snowpack almost certainly could not have survived for 70,000 years. For most of the parameter settings snowpack interior temperatures at this latitude and slope do reach the melting point. Under most conditions melting occurs when the snowpack is less than 10 cm thick. The modeled snowpack will not melt if it is covered by a 1 cm dust lag. In general, these findings raise interesting possibilities regarding gully formation, but perhaps mostly during a past climate regime when snowfall was expected to have occurred. If there currently are exposed snowpacks on martian mid-latitude slopes, then these ice sheets cannot last long. Hence they might be time variable features on Mars and should be searched for.

Published
2008

44. Observations of martian gullies and constraints on potential formation mechanisms

Author

Michael T. Mellon, Owen B. Toon, Ella Carlsson, Jennifer L. Heldmann, and Henrik Johansson

Subjects
Martian, geography, Thermal Emission Spectrometer, geography.geographical_feature_category, Meteorology, Landform, Northern Hemisphere, Astronomy and Astrophysics, Mars Exploration Program, Impact crater, Space and Planetary Science, Mars Orbiter Laser Altimeter, Geomorphology, Southern Hemisphere, Geology
Abstract

The formation process(es) responsible for creating the observed geologically recent gully features on Mars has remained the subject of intense debate since their discovery. We present new data and analysis of northern hemisphere gullies from Mars Global Surveyor data which is used to test the various proposed mechanisms of gully formation. We located 137 Mars Orbiter Camera (MOC) images in the northern hemisphere that contain clear evidence of gully landforms and analyzed these images in combination with Mars Orbiter Laser Altimeter (MOLA) and Thermal Emission Spectrometer (TES) data to provide quantitative measurements of numerous gully characteristics. Parameters we measured include apparent source depth and distribution, vertical and horizontal dimensions, slopes, orientations, and present-day characteristics that affect local ground temperatures. Northern hemisphere gullies are clustered in Arcadia Planitia, Tempe Terra, Acidalia Planitia, and Utopia Planitia. These gullies form in craters (84%), knobby terrain (4%), valleys (3%), other/unknown terrains (9%) and are found on all slope orientations although the majority of gullies are equator-facing. Most gullies (63%) are associated with competent rock strata, 26% are not associated with strata, and 11% are ambiguous. Assuming thermal conductivities derived from TES measurements as well as modeled surface temperatures, we find that 95% of the gully alcove bases with adequate data coverage lie at depths where subsurface temperatures are greater than 273 K and 5% of the alcove bases lie within the solid water regime. The average alcove length is 470 m and the average channel length is 690 m. Based on a comparison of measured gully features with predictions from the various models of gully formation, we find that models involving carbon dioxide, melting ground ice in the upper few meters of the soil, dry landslide, and surface snowmelt are the least likely to describe the formation of the martian gullies. Although some discrepancies still exist between prediction and observation, the shallow and deep aquifer models remain as the most plausible theories. Interior processes involving subsurface fluid sources are generally favored over exogenic processes such as wind and snowfall for explaining the origin of the martian gullies. These findings gleaned from the northern hemisphere data are in general agreement with analyses of gullies in the southern hemisphere [Heldmann, J.L., Mellon, M.T., 2004. Icarus 168, 285–304].

Published
2007

45. Gully

Author

Jennifer L. Heldmann, Serina Diniega, Ákos Kereszturi, and Susan J. Conway

Published
2015

46. Observations of martian gullies and constraints on potential formation mechanisms

Author

Jennifer L. Heldmann and Michael T. Mellon

Subjects
Martian, geography, Thermal Emission Spectrometer, geography.geographical_feature_category, Landform, Astronomy and Astrophysics, Landslide, Mars Exploration Program, Space and Planetary Science, Ridge, Mars Orbiter Laser Altimeter, Geomorphology, Geology, Alcove, Remote sensing
Abstract

The discovery of presumably geologically recent gully features on Mars (Malin and Edgett, 2000, Science 288, 2330–2335) has spawned a wide variety of proposed theories of their origin including hypotheses of the type of erosive material. To test the validity of gully formation mechanisms, data from the Mars Global Surveyor spacecraft has been analyzed to uncover trends in the dimensional and physical properties of the gullies and their surrounding terrain. We located 106 Mars Orbiter Camera (MOC) images that contain clear evidence of gully landforms, distributed in the southern mid and high latitudes, and analyzed these images in combination with Mars Orbiter Laser Altimeter (MOLA) and Thermal Emission Spectrometer (TES) data to provide quantitative measurements of numerous gully characteristics. Parameters we measured include apparent source depth and distribution, vertical and horizontal dimensions, slopes, orientations, and present-day characteristics that affect local ground temperatures. We find that the number of gully systems normalized to the number of MOC images steadily declines as one moves poleward of 30° S, reaches a minimum value between 60°–63° S, and then again rises poleward of 63° S. All gully alcove heads occur within the upper one-third of the slope encompassing the gully and the alcove bases occur within the upper two-thirds of the slope. Also, the gully alcove heads occur typically within the first 200 meters of the overlying ridge with the exception of gullies equatorward of 40° S where some alcove heads reach a maximum depth of 1000 meters. While gullies exhibit complex slope orientation trends, gullies are found on all slope orientations at all the latitudes studied. Assuming thermal conductivities derived from TES measurements as well as modeled surface temperatures, we find that 79% of the gully alcove bases lie at depths where subsurface temperatures are greater than 273 K and 21% of the alcove bases lie within the solid water regime. Most of the gully alcoves lie outside the temperature–pressure phase stability of liquid CO2. Based on a comparison of measured gully features with predictions from the various models of gully formation, we find that models involving carbon dioxide, melting ground ice in the upper few meters of the soil, dry landslide, and surface snowmelt are the least likely to describe the formation of the martian gullies. Although some discrepancies still exist between prediction and observation, the shallow and deep aquifer models remain as the most plausible theories. Interior processes involving subsurface fluid sources are generally favored over exogenic processes such as wind and snowfall for explaining the origin of the martian gullies.

Published
2004

47. Midlatitude ice-rich ground on mars as a target in the search for evidence of life and for in situ resource utilization on human missions

Author

Carol R. Stoker, C. P. McKay, Alfonso F. Davila, Mary Beth Wilhelm, Jennifer L. Heldmann, L. R. Schurmeier, and Margarita M. Marinova

Subjects
Extraterrestrial Environment, Habitability, United States National Aeronautics and Space Administration, Ice, Mars, In situ resource utilization, Mars Exploration Program, Space Flight, Life on Mars, Agricultural and Biological Sciences (miscellaneous), Ground ice, Proxy (climate), United States, Astrobiology, Space and Planetary Science, Middle latitudes, Exobiology, Environmental science, Astronauts
Abstract

Midlatitude ground ice on Mars is of significant scientific interest for understanding the history and evolution of ice stability on Mars and is relevant for human exploration as a possible in situ resource. For both science and exploration, assessing the astrobiological potential of the ice is important in terms of (1) understanding the potential for life on Mars and (2) evaluating the presence of possible biohazards in advance of human exploration. In the present study, we review the evidence for midlatitude ground ice on Mars, discuss the possible explanations for its occurrence, and assess its potential habitability. During the course of study, we systematically analyzed remote-sensing data sets to determine whether a viable landing site exists in the northern midlatitudes to enable a robotic mission that conducts in situ characterization and searches for evidence of life in the ice. We classified each site according to (1) presence of polygons as a proxy for subsurface ice, (2) presence and abundance of rough topographic obstacles (e.g., large cracks, cliffs, uneven topography), (3) rock density, (4) presence and abundance of large boulders, and (5) presence of craters. We found that a suitable landing site exists within Amazonis Planitia near ground ice that was recently excavated by a meteorite impact.

Published
2014

48. Gully

Author

Jennifer L. Heldmann, Serina Diniega, Ákos Kereszturi, and Susan J. Conway

Published
2014

49. The NASA Spaceward Bound field training curriculum

Author

Jon Rask, Christopher P. McKay, Heather D. Smith, Melissa Battler, and Jennifer L. Heldmann

Subjects
Engineering, Medical education, Engineering management, business.industry, business, Field training, Curriculum
Published
2011

50. 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

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