Search

Your search keyword '"Anna Grau Galofre"' showing total 23 results
Start Over Author "Anna Grau Galofre"
23 results on '"Anna Grau Galofre"'

1. High Arctic channel incision modulated by climate change and the emergence of polygonal ground

Author

Shawn M. Chartrand, A. Mark Jellinek, Antero Kukko, Anna Grau Galofre, Gordon R. Osinski, and Shannon Hibbard

Subjects
Science
Abstract

Abstract Stream networks in Arctic and high-elevation regions underlain by frozen ground (i.e., permafrost) are expanding and developing in response to accelerating global warming, and intensifying summertime climate variability. The underlying processes governing landscape dissection in these environments are varied, complex and challenging to unravel due to air-temperature-regulated feedbacks and shifts to new erosional regimes as climate change progresses. Here we use multiple sources of environmental information and physical models to reconstruct and understand a 60-year history of landscape-scale channelization and evolution of the Muskox Valley, Axel Heiberg Island. A time series of air photographs indicates that freeze-thaw-related polygon fields can form rapidly, over decadal time scales. Supporting numerical simulations show that the presence of polygons can control how surface runoff is routed through the landscape, exerting a basic control on channelization, which is sensitive to the timing, duration and magnitude of hydrograph events, as well as seasonal air temperature trends. These results collectively highlight that the occurrence and dynamics of polygon fields modulate channel network establishment in permafrost-rich settings undergoing changes related to a warming climate.

Published
2023
Full Text
View/download PDF

3. The morphology of glacier-associated layered deposits on Mars

Author

Susan Conway, Frances Butcher, Anna Grau Galofre, and Axel Noblet

Abstract

Mars is thought to have been a hyperarid desert for at least the last one billion years of its history and so water is locked up in the two polar ice caps, ground ice and an extensive band of debris covered glaciers found in the mid-latitudes. Layers expressed by the polar caps are thought to record the most recent climate cycles of Mars – up to a few tens of Ma. The debris covered glaciers are thought to date to hundreds of millions of years in age and potentially record a deeper climate record. Here, we report on the widespread occurrence of layered outcrops intimately associated with glaciated terrains in Deuteronilus Mensae and the Eastern Hellas region – two areas renowned for their extremely extensive and well-preserved debris covered glaciers. We explore the relationship between these layered outcrops and the debris covered glaciers by exploiting images and elevation data from the High Resolution Science Imaging Experiment (HiRISE) at 25 cm/pixel, Context camera (CTX) at 6 m/pixel and Colour and Stereo Imaging System (CaSSIS) at 4.5 m/pixel. Because these outcrops have similar morphology in both the northern and the southern hemisphere they point to a globally relevant process. Our aim is to test the hypothesis that these deposits represent remnant glacial deposits, which could give information of Mars climate beyond that obtainable by studying the polar caps.

Published
2022

4. Diving into the icy origins of Martian valleys

Author

Anna Grau Galofre

Abstract

Mars is nowadays a frozen desert devoid of liquid water, but it was not always like this: giant valleys and canyons on its surface show that at some point in the remote past, water existed on the Martian surface. Trying to understand the origin of these valleys, we found answers in an unexpected place: the plumbing system of ice sheets.

Published
2022

5. The (missing) erosional record of warm-based glaciation on early Mars

Author

Anna Grau Galofre, Kelin Whipple, and Philip Christensen

Abstract

The lack of evidence for large-scale glacial erosion on Mars has led to the belief that any ice sheet that may have existed had to be frozen to the ground. We challenge this argument, suggesting instead that the fingerprints of Martian warm-based ice masses should be the remnants of their drainage systems, including channel networks and eskers, instead of the large scoured fields generally associated with terrestrial Quaternary glaciation. Our results use the terrestrial glacial hydrology framework to interrogate how the Martian lower surface gravity should affect the state and evolution of the glacial drainage system, ice sliding velocity, and the rates of glacial erosion. Taking as reference the scale and characteristics of the ancient southern circumpolar ice sheet that deposited the Dorsa Argentea formation, we compare the theoretical behavior of geometrically identical ice sheets on Mars and Earth and show that, whereas on Earth glacial drainage is predominantly inefficient, enhancing ice sliding and producing characteristically scoured glacial landscapes, on Mars the lower gravity favors the formation of efficient subglacial channelized drainage. The apparent lack of large-scale glacial fingerprints on Mars, such as scouring marks, drumlins, lineations, etc., is thus to be expected.

Published
2022

6. Valley formation on early Mars by subglacial and fluvial erosion

Author

A. Mark Jellinek, Anna Grau Galofre, and Gordon R. Osinski

Subjects
geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Earth science, Fluvial, Mars Exploration Program, 010502 geochemistry & geophysics, Geologic record, 01 natural sciences, Erosion, General Earth and Planetary Sciences, Groundwater sapping, Glacial period, Ice sheet, Surface runoff, Geology, 0105 earth and related environmental sciences
Abstract

The southern highlands of Mars are dissected by hundreds of valley networks, which are evidence that water once sculpted the surface. Characterizing the mechanisms of valley incision may constrain early Mars climate and the search for ancient life. Previous interpretations of the geological record require precipitation and surface water runoff to form the valley networks, in contradiction with climate simulations that predict a cold, icy ancient Mars. Here we present a global comparative study of valley network morphometry, using a principal-component-based analysis with physical models of fluvial, groundwater sapping and glacial and subglacial erosion. We found that valley formation involved all these processes, but that subglacial and fluvial erosion are the predominant mechanisms. This is supported by predictions from models of steady-state erosion and geomorphological comparisons to terrestrial analogues. The inference of subglacial channels among the valley networks supports the presence of ice sheets that covered the southern highlands during the time of valley network emplacement. Some valleys in the southern highlands of Mars may have formed by subglacial erosion, consistent with a cold and icy early Mars, according to a statistical analysis of valley morphometry.

Published
2020

8. CanMars mission Science Team operational results: Implications for operations and the sample selection process for Mars Sample Return (MSR)

Author

S. L. Simpson, Gordon R. Osinski, Anna Grau Galofre, E. Godin, Livio L. Tornabene, J. T. Poitras, C. M. Caudill, Anna Mittelholz, Melissa Battler, R. Francis, Matthew Svensson, V. Hipkin, Z. R. Morse, T. Haltigin, Eric A. Pilles, Alexandra Pontefract, and Tianqi Xie

Subjects
Engineering, Mars sample return, Mission operations, 010504 meteorology & atmospheric sciences, business.industry, Habitability, Best practice, Testbed, Astronomy and Astrophysics, Mars Exploration Program, 01 natural sciences, Documentation, Workflow, Space and Planetary Science, 0103 physical sciences, Systems engineering, business, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences
Abstract

The CanMars Mars sample return (MSR) analogue mission was conducted as a field and operational test for the Mars 2020 sample cache rover mission and was the most realistic known MSR rover analogue mission to-date. A rover — similar in scale to that of rover planned for NASA's Mars 2020 mission — was deployed to a scientifically relevant Mars-analogue sedimentary field site with remote mission operations conducted at the University of Western Ontario, Canada; the mission aim was to inform on best practices and optimal approaches for sample acquisition modeled on the Mars 2020 rover mission. The daily operational procedures of the CanMars Science Team were modeled on those of current missions (i.e., Mars Science Laboratory tactical operations), serving as a study of known operational workflows and as a testbed for new approaches. This paper reports on the operational results of CanMars with best-practice recommendations. CanMars was designed as a Mars 2020 mock mission and thus carried similar science objectives; these included (1) advancing the understanding of the habitability potential of a subaqueous sedimentary environment through identifying, characterizing, and caching drilled samples containing high organic carbon (as a proxy for preserved ancient biosignatures) and (2) advancing the understanding of the history of water at the site. The in situ science investigations needed to address these science objectives were guided by the Mars Exploration Program Analysis Group goals. Effective and efficient Science Team operational procedures were developed – and many lessons were documented – through daily tactical planning and science investigations employed to meet the sample acquisition goals. In addition to the documentation of the CanMars operational procedures, this paper provides a brief summary of the science results from CanMars with a focus on recommendations for future analogue missions and planetary sample return flight missions, providing specific value to operational procedures for the Mars 2020 rover mission.

Published
2019

9. The CanMars Mars Sample Return analogue mission

Author

Derek King, T. Haltigin, A. Bina, C. L. Marion, Jackie Goordial, Racel Sopoco, E. A. Lymer, Tom Dzamba, Anna Grau Galofre, E. M. Harrington, Martin Picard, R. Francis, K. Balachandran, C. M. Caudill, Liam Robert John Innis, P. A. Christoffersen, S. Duff, Elizabeth A. Silber, Alexandra Pontefract, Joshua Laughton, Rebecca Wilks, M. C. Kerrigan, Yaozhu Li, Edward A. Cloutis, Dylan Hickson, Daniel Bednar, Kristen Cote, C. H. Ryan, Tanya N. Harrison, Omar Draz, M. Bourassa, Tianqi Xie, Paul Fulford, Melissa Battler, Ian Pritchard, J. W. O’Callaghan, E. Godin, Eric A. Pilles, Matthew Svensson, Matthew Maloney, Sarah Mcfadden, Matthew Cross, P. Patel, David Beaty, J. D. Newman, John Maris, Scott M. McLennan, Kenneth H. Williford, Pierre Allard, Fenge Cao, Haley M. Sapers, Alexis David P. Pascual, Bryce Dudley, Diego Uribe, V. Hipkin, Z. R. Morse, Anna Mittelholz, Taylor Haid, W. Zylberman, Bianca D'Aoust, Catherine Maggiori, J. T. Poitras, Byung-Hun Choe, Gordon R. Osinski, Livio L. Tornabene, J. Hawkswell, P. J. A. Hill, Jonathan Kissi, G. D. Tolometti, S. L. Simpson, and Joseph Nsasi Bakambu

Subjects
Operations architecture, Mission control center, 010504 meteorology & atmospheric sciences, Payload, Astronomy and Astrophysics, Sample (statistics), Mars Exploration Program, Exploration of Mars, 01 natural sciences, Space exploration, Outreach, Space and Planetary Science, 0103 physical sciences, Systems engineering, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences
Abstract

The return of samples from known locations on Mars is among the highest priority goals of the international planetary science community. A possible scenario for Mars Sample Return (MSR) is a series of 3 missions: sample cache, fetch, and retrieval. The NASA Mars 2020 mission represents the first cache mission and was the focus of the CanMars analogue mission described in this paper. The major objectives for CanMars included comparing the accuracy of selecting samples remotely using rover data versus a traditional human field party, testing the efficiency of remote science operations with periodic pre-planned strategic observations (Strategic Traverse Days), assessing the utility of realistic autonomous science capabilities to the remote science team, and investigating the factors that affect the quality of sample selection decision-making in light of returned sample analysis. CanMars was conducted over two weeks in November 2015 and continued over three weeks in October and November 2016 at an analogue site near Hanksville, Utah, USA, that was unknown to the Mission Control Team located at the University of Western Ontario (Western) in London, Ontario, Canada. This operations architecture for CanMars was based on the Phoenix and Mars Exploration Rover missions together with previous analogue missions led by Western with the Mission Control Team being divided into Planning and Science sub-teams. In advance of the 2015 operations, the Science Team used satellite data, chosen to mimic datasets available from Mars-orbiting instruments, to produce a predictive geological map for the landing ellipse and a set of hypotheses for the geology and astrobiological potential of the landing site. The site was proposed to consist of a series of weakly cemented multi-coloured sedimentary rocks comprising carbonates, sulfates, and clays, and sinuous ridges with a resistant capping unit, interpreted as inverted paleochannels. Both the 2015 CanMars mission, which achieved 11 sols of operations, and the first part of the 2016 mission (sols 12–21), were conducted with the Mars Exploration Science Rover (MESR) and a series of integrated and hand-held instruments designed to mimic the payload of the Mars 2020 rover. Part 2 of the 2016 campaign (sols 22–39) was implemented without the MESR rover and was conducted exclusively by the field team as a Fast Motion Field Test (FMFT) with hand-carried instruments and with the equivalent of three sols of operations being executed in a single actual day. A total of 8 samples were cached during the 39 sols from which the Science Team prioritized 3 for “return to Earth”. Various science autonomy capabilities, based on flight-proven or near-future techniques intended for actual rover missions, were tested throughout the 2016 CanMars activities, with autonomous geological classification and targeting and autonomous pointing refinement being used extensively during the FMFT. Blind targeting, contingency sequencing, and conditional sequencing were also employed. Validation of the CanMars cache mission was achieved through various methods and approaches. The use of dedicated documentarians in mission control provided a detailed record of how and why decisions were made. Multiple separate field validation exercises employing humans using traditional geological techniques were carried out. All 8 of the selected samples plus a range of samples from the landing site region, collected out-of-simulation, have been analysed using a range of laboratory analytical techniques. A variety of lessons learned for both future analogue missions and planetary exploration missions are provided, including: dynamic collaboration between the science and planning teams as being key for mission success; the more frequent use of spectrometers and micro-imagers having remote capabilities rather than contact instruments; the utility of strategic traverse days to provide additional time for scientific discussion and meaningful interpretation of the data; the benefit of walkabout traverse strategies along with multi-sol plans with complex decisions trees to acquire a large amount of contextual data; and the availability of autonomous geological targeting, which enabled complex multi-sol plans gathering large suites of geological and geochemical survey data. Finally, the CanMars MSR activity demonstrated the utility of analogue missions in providing opportunities to engage and educate children and the public, by providing tangible hands-on linkages between current robotic missions and future human space missions. Public education and outreach was a priority for CanMars and a dedicated lead coordinated a strong presence on social media (primarily Twitter and Facebook), articles in local, regional, and national news networks, and interaction with the local community in London, Ontario. A further core objective of CanMars was to provide valuable learning opportunities to students and post-doctoral fellows in preparation for future planetary exploration missions. A learning goals survey conducted at the end of the 2016 activities had 90% of participants “somewhat agreeing” or “strongly agreeing” that participation in the mission has helped them to increase their understanding of the four learning outcomes.

Published
2019

10. Solar-System-Wide Significance of Mars Polar Science

Author

J. J. Plaut, Colman Gallagher, Stephen R. Lewis, J. Bapst, C. Andres, John F. Mustard, S. F. A. Cartwright, Lauren A. Edgar, Susan J. Conway, Alan D. Howard, Michael Mischna, Gareth A. Morgan, Maria E. Banks, S. Diniega, Mark L. Skidmore, A. Van Brenen, Carol R. Stoker, Ralf Jaumann, Charity M. Phillips-Lander, Ali M. Bramson, Jennifer L. Whitten, Michael Daly, Michael H. Hecht, Solmaz Adeli, Manish R. Patel, N. Oliveira, S. Mukherjee, Matthew Chojnacki, Kimberly D. Seelos, F. Foss, S. Nerozzi, John E. Moores, Patricio Becerra, Nathaniel E. Putzig, Michael T. Mellon, Vince Eke, Margaret E. Landis, P. B. James, U. Gayathri, F. Bernardini, John Wilson, J. M. Widmer, J. Chesal, Alexey A. Pankine, Klaus-Michael Aye, C. Stuurman, Andrea Coronato, Z. Yoldi, C. Rezza, L. E. McKeown, Edwin S. Kite, B. Hartmann, Ákos Kereszturi, Melinda A. Kahre, Kennda Lynch, M. M. Sori, Alain Khayat, A. Kleinboehl, Matteo Crismani, Scott D. Guzewich, L. R. Lozano, Daniel J. McCleese, Norbert Schorghofer, O. Karatekin, Cynthia L. Dinwiddie, Gordon R. Osinski, Lori K. Fenton, Luca Montabone, Andreas Johnsson, Roberto Orosei, Peter C. Thomas, J. P. Knightly, Matthew R. Balme, Claire E. Newman, Eldar Noe Dobrea, Joseph A. MacGregor, Ernst Hauber, A. C. Pascuzzo, Jennifer Hanley, Bryana L. Henderson, Oded Aharonson, German Martinez, Timothy N. Titus, M. R. Perry, Tanguy Bertrand, P. A. Johnson, Maurizio Pajola, Shane Byrne, Matthew A. Siegler, Anya Portyankina, Nicolas Thomas, R. Karimova, C. Orgel, Michelle Koutnik, Leslie K. Tamppari, Amy McAdam, James A. Whiteway, Briony Horgan, Frances E. G. Butcher, E. Vos, François Forget, Christine S. Hvidberg, Vincent Chevrier, Travis F. Hager, Roland M. B. Young, T. G. Cave, Peter L. Read, M. R. Elmaary, Shannon M. Hibbard, C. J. Hansen, Paul O. Hayne, David A. Crown, J. C. Stern, J. C. Echaurren, I. Mishev, P. Russell, Roger N. Clark, Hanna G. Sizemore, J. W. Holt, F. Chuang, Adrian J. Brown, Colin M. Dundas, S. Ulamsec, G. Luizzi, Isaac B. Smith, Anna Łosiak, Peter Fawdon, David L. Goldsby, Alfred S. McEwen, C. Amos, S. E. Wood, C. Cesar, David E. Stillman, R. W. Obbard, Ralph D. Lorenz, A. Svensson, Ryan C. Ewing, Aymeric Spiga, B. S. Tober, T. Meng, P. Acharya, S. M. Milkovich, Paul Streeter, Kris Zacny, P. Sinha, Joseph S. Levy, Don Banfield, Eric I. Petersen, K. E. Herkenhoff, J. L. Eigenbrode, S. Piqueux, Mackenzie Day, Renyu Hu, Gregory Michael, James W. Head, Alejandro Soto, Richard Massey, A. R. Khuller, P. B. Buhler, S. Clifford, Samuel P. Kounaves, Daniel C. Berman, K. E. Mesick, Bernard Schmitt, Wendy M. Calvin, J. C. Johnson, David A. Fisher, C. Neisch, Robert L. Staehle, C. Herny, D. E. Lalich, Edgard G. Rivera-Valentín, David E. Smith, Anshuman Bhardwaj, Jorge Rabassa, Anna Grau Galofre, Alice Lucchetti, Lydia Sam, A. M. Rutledge, and A. J. Cross

Subjects
polar science, geology, Solar System, Habitability, water, ice, Mars, Mars Exploration Program, Astrobiology, missions, Planetary science, Planet, Polar, Climate record, climate, Geology
Abstract

Mars Polar Science is an integrated, compelling system that serves as a nearby analogue to numerous other planets, supports human exploration, and habitability. Mars possesses the closest and most easily accessible layered ice deposits outside of Earth, and accessing those layers to read the climate record would be a triumph for planetary science.

Published
2021

11. The Importance of the Climate Record in the Martian Polar Layered Deposits

Author

Patricio Becerra, M. M. Sori, Shane Byrne, Jennifer L. Whitten, Briony Horgan, Jeffrey J. Plaut, S. Diniega, Ali M. Bramson, Ganna Portyankina, Leslie K. Tamppari, Margaret E. Landis, Christine S. Hvidberg, Paul O. Hayne, Andrea Coronato, Nicolas Thomas, Jorge Rabassa, Adrian J. Brown, A. C. Pascuzzo, Anna Grau Galofre, Isaac B. Smith, Nathaniel E. Putzig, and R. W. Obbard

Subjects
Martian, Polar, Climate record, Geology, Astrobiology
Published
2021

12. Mars as a 'natural laboratory' for studying surface activity on a range of planetary bodies

Author

Ali M. Bramson, Matthew Chojnacki, Alfred S. McEwen, P. B. Buhler, Devon M. Burr, Bonnie J. Buratti, J. M. Widmer, Anya Portyankina, Scot Rafkin, Lauren McKeown, Brian Jackson, Susan J. Conway, Ingrid Daubar, Isaac B. Smith, Simone Silvestro, Cynthia L. Dinwiddie, Mathieu G.A. Lapotre, Anna Grau Galofre, C. Swann, Joseph S. Levy, S. Piqueux, and S. Diniega

Subjects
Surface (mathematics), Range (biology), Mars Exploration Program, Geology, Natural (archaeology), Astrobiology
Published
2021

13. A comparative view of glacial and periglacial landforms on Earth and Mars

Author

Frances E. G. Butcher, Shannon M. Hibbard, Philip R. Christensen, Anshuman Bhardwaj, Jorge Rabassa, Kelin X. Whipple, Anna Grau Galofre, Ali M. Bramson, Tyler McGrew Meng, Jayanth Serla, E. I. Petersen, Lydia Sam, Andrea Coronato, Ernst Hauber, Gordon R. Osinski, A. M. Rutledge, J. J. Plaut, C. Andres, Patricio Becerra, J. Paul Knightly, and Susan J. Conway

Subjects
Martian, geography, geography.geographical_feature_category, Landform, water, ice, Mars, Geology, Mars Exploration Program, Natural (archaeology), Astrobiology, missions, Cryosphere, Earth (chemistry), Glacial period, climate, permafrost
Abstract

This paper emphasizes the importance of using terrestrial analogues to improve our understanding of the role of ice on Mars through its associated landforms. We discuss terrestrial regions and techniques that can help understand Martian icy environments, and highlight the necessity to explore the Martian cryosphere as the next natural step.

Published
2021

14. Discordance Mapping of Argyre Basin: An Insight into the Fluvial and Subglacial Origin of Valley Networks in the Argyre Basin Region

Author

Merren Jones, Neil C. Mitchell, Anna Grau Galofre, Rickbir Bahia, and S. J. Covey-Crump

Subjects
Paleontology, Fluvial, Structural basin, Geology
Abstract

Introduction: Martian valley networks are evidence for surface run-off and past water cycles on ancient Mars. Many of the networks resemble terrestrial precipitation-fed systems; however, recent analysis has found that the geometries and morphological characteristics of some valley networks are more comparable to subglacial valley formation. Subglacial valleys have morphological characteristics that make them distinct from fluvial valley systems (i.e., those formed via precipitation or sapping erosion). Unlike fluvial valley networks, which follow the surface slope of the underlying topography, sub-glacial networks are orientated in the direction of the surface slope of the overlying ice-sheet. Therefore, subglacial valleys may have orientations that are discordant with the underlying topography. Discordance analysis, a technique that compares the valley paleoslope direction and topographic slope direction, has been applied to Mars to determine areas that have undergone topographic modification since valley formation. This technique could also be a tool for identify valleys with potential sub-glacial origins.In this study, we mapped and applied discordance analysis to valley networks in and around Argyre basin. Detailed analysis was performed on four valley networks on eastern Argyre, to determine whether their characteristics are indicative of a fluvial or sub-glacial origin.Results: 2669 V-Shaped valleys (total length = 36155.5 km) and 45 U-Shaped valleys (total length = 2683.5 km) were identified. Most V-Shaped valleys dissect the eastern and northern rim of Argyre Basin, with fewer in the south and west. The densest northern valley networks have values up to 0.098 km-1, compared to the densest in the south with values of only 0.040 km-1. U-Shaped valleys are prominent along the south/south-west rim, but are lacking along the northern rim of Argyre.Most valleys (47.8 %) are concordant (< 45° discordance) with present slope direction. Two dense groups of discordant valleys are present adjacent to Hale Crater and Nia Vallis. These areas display features associated with the presence of an ice-sheet/glacier – e.g., glacial moraines and eskers. Additionally, the morphology of these valley systems are consistent with a subglacial origin.Fento Vallis and the Darwin Crater valley system are concordant with present topographic slope, and are in close proximity to one another; however, their morphologies differ greatly. Fento Vallis consists of 25 valleys (total valley length of ~ 690 km) and drainage density of 0.019 km-1. The Darwin Crater valley network consists of 49 valleys (total valley length of ~ 1351 km) and drainage density of 0.048 km-1. Fento Vallis displays features (e.g., inner channel eskers) indicative of a subglacial origin. Alternatively, the Darwin Crater System has a planform associated with fluvial activity and originates from cirque like depressions. Although the Darwin Crater system appears to have a fluvial origin, less than 100 km to the east is Pallacopas Vallis, which displays inner eskers indicating that it has a subglacial origin.Three of the networks analysed, which are > 1000 km apart from one another, are likely subglacial in origin. Their occurrence indicates that an ice-sheet or multiple ice-sheets were present along the eastern region of Argyre throughout its history.

Published
2021

16. Did Martian valley networks substantially modify the landscape?

Author

Rickbir Bahia, A. Mark Jellinek, Kelin X. Whipple, Anna Grau Galofre, and Rose Gallo

Subjects
010504 meteorology & atmospheric sciences, Water source, Fluvial, Mars, precipitation, 010502 geochemistry & geophysics, 01 natural sciences, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Precipitation, fluvial erosion, Southern Hemisphere, 0105 earth and related environmental sciences, Martian, valley networks, Maturity (sedimentology), Mars Exploration Program, 15. Life on land, Network activity, Geophysics, 13. Climate action, Space and Planetary Science, profile analysis, Physical geography, maturity, Geology
Abstract

Valley networks are ancient drainage systems incised on the southern hemisphere of Mars, and stand as evidence that liquid water once sculpted its surface. The duration of valley network activity and the sources of water are key questions in deciphering the timing of water stability on early Mars, but remain poorly constrained. In this study we address two questions: Did Martian valley networks evolve for sufficiently long to establish their own erosional basins, or do their profiles primarily reflect landscape pre-incision topography? And were these valleys precipitation-fed or spring-fed? Our analysis uses the theoretical framework built to describe the shape of steady-state river profiles on Earth to compare and analyze the concavity of 62 valley network longitudinal profiles on Mars. Using non-linear fits to valley profiles we evaluate the degree to which valley networks are consistent with fluvial steady-state. The fit enables the identification of valley network concavity index and area-discharge exponent, which we then interpret in terms of the theoretical framework to discuss valley network maturity and water source. Our results show that the majority of valley networks do not have concave or even smooth profiles, and did not substantially modify their surrounding landscape. We observe disparity in concavity indexes of valley networks belonging in the same integrated basins, indicating different stages of landscape evolution and lack of synchronous valley development. However, our results identify six valley networks consistent with fluvial steady-state and areally uniform precipitation.

Published
2020

17. Subglacial drainage patterns of Devon Island, Canada: detailed comparison of rivers and subglacial meltwater channels

Author

Michael Zanetti, Anna Grau Galofre, Antero Kukko, A. Mark Jellinek, Gordon R. Osinski, National Land Survey of Finland, and Maanmittauslaitos

Subjects
lcsh:GE1-350, geography, Subglacial channel, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Ice stream, lcsh:QE1-996.5, Channelized, 15. Life on land, 010502 geochemistry & geophysics, 01 natural sciences, lcsh:Geology, Arctic, 13. Climate action, Tributary, Erosion, Ice sheet, Meltwater, Geomorphology, Geology, lcsh:Environmental sciences, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology
Abstract

Subglacial meltwater channels (N-channels) are attributed to erosion by meltwater in subglacial conduits. They exert a major control on meltwater accumulation at the base of ice sheets, serving as drainage pathways and modifying ice flow rates. The study of exposed relict subglacial channels offers a unique opportunity to characterize the geomorphologic fingerprint of subglacial erosion as well as study the structure and characteristics of ice sheet drainage systems. In this study we present detailed field and remote sensing observations of exposed subglacial meltwater channels in excellent preservation state on Devon Island (Canadian Arctic Archipelago). We characterize channel cross section, longitudinal profiles, and network morphologies and establish the spatial extent and distinctive characteristics of subglacial drainage systems. We use field-based GPS measurements of subglacial channel longitudinal profiles, along with stereo imagery-derived digital surface models (DSMs), and novel kinematic portable lidar data to establish a detailed characterization of subglacial channels in our field study area, including their distinction from rivers and other meltwater drainage systems. Subglacial channels typically cluster in groups of ∼10 channels and are oriented perpendicular to active or former ice margins. Although their overall direction generally follows topographic gradients, channels can be oblique to topographic gradients and have undulating longitudinal profiles. We also observe that the width of first-order tributaries is 1 to 2 orders of magnitude larger than in Devon Island river systems and approximately constant. Furthermore, our findings are consistent with theoretical expectations drawn from analyses of flow driven by gradients in effective water pressure related to variations in ice thickness. Our field and remote sensing observations represent the first high-resolution study of the subglacial geomorphology of the high Arctic, and provide quantitative and qualitative descriptions of subglacial channels that revisit well-established field identification guidelines. Distinguishing subglacial channels in topographic data is critical for understanding the emergence, geometry, and extent of channelized meltwater systems and their role in ice sheet drainage. The final aim of this study is to facilitate the identification of subglacial channel networks throughout the globe by using remote sensing techniques, which will improve the detection of these systems and help to build understanding of the underlying mechanics of subglacial channelized drainage.

Published
2018

18. Past, Present, and Future of Mars Polar Science: Outcomes and Outlook from the 7th International Conference on Mars Polar Science and Exploration

Author

Zuriñe Yoldi, Andrea Coronato, Ganna Portyankina, Melinda A. Kahre, Patricio Becerra, Isaac Smith, J. Bapst, Leslie K. Tamppari, A. C. Pascuzzo, Jennifer L. Whitten, Anna Grau Galofre, P. B. Buhler, C. Herny, Serina Diniega, C. Andres, S. Nerozzi, J. Paul Knightly, Timothy N. Titus, Jorge Rabassa, Shannon M. Hibbard, Ali M. Bramson, and Jeremy Emmett

Subjects
0211 other engineering and technologies, Astronomy and Astrophysics, 02 engineering and technology, Mars Exploration Program, 010502 geochemistry & geophysics, 01 natural sciences, Astrobiology, Geophysics, Space and Planetary Science, Earth and Planetary Sciences (miscellaneous), Polar, Geology, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences
Abstract

Mars Polar Science is a subfield of Mars science that encompasses all studies of the cryosphere of Mars and its interaction with the Martian environment. Every 4 yr, the community of scientists dedicated to this subfield meets to discuss new findings and debate open issues in the International Conference on Mars Polar Science and Exploration (ICMPSE). This paper summarizes the proceedings of the seventh ICMPSE and the progress made since the sixth edition. We highlight the most important advances and present the most salient open questions in the field today, as discussed and agreed upon by the participants of the conference. We also feature agreed-upon suggestions for future methods, measurements, instruments, and missions that would be essential to answering the main open questions presented. This work is thus an overview of the current status of Mars Polar Science and is intended to serve as a road map for the direction of the field during the next 4 yr and beyond, helping to shape its contribution within the larger context of planetary science and exploration.

Published
2021

19. The geometry and complexity of spatial patterns of terrestrial channel networks: Distinctive fingerprints of erosional regimes

Author

Anna Grau Galofre and A. Mark Jellinek

Subjects
010504 meteorology & atmospheric sciences, Fluvial, Geometry, 010502 geochemistry & geophysics, 01 natural sciences, Fractal dimension, Geophysics, Erosion, Spatial ecology, Groundwater sapping, Meltwater, Digital elevation model, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes, Communication channel
Abstract

The morphology of channel networks related to long-term erosion reflects the mechanisms involved in their formation. This study aims to identify quantitative metrics, drawn from topographic data and satellite imagery, that are diagnostic of the distinctive styles of erosion by rivers, glaciers, subglacial meltwater, and groundwater sapping. From digital elevation models, we identify three geometric metrics: the minimum channel width, channel aspect ratio (longest length to channel width at the outlet), and tributary junction angle. We also characterize channel network complexity in terms of its stream order and fractal dimension. To validate our approach, we perform a principal component analysis (PCA) on measurements of these five metrics on 70 channel networks. We build understanding of these results, in turn using scaling analyses of appropriate physical models. We show that rivers, glaciers, and groundwater sapping erode the landscape in rigorously distinguishable ways. Whereas rivers are characterized by nearly constant minimum width, variable aspect ratio, and high stream orders, glaciers have highly variable minimum widths and aspect ratios and much smaller stream orders. Erosion by subglacial meltwater remains poorly understood, and we argue that we require an additional metric to fully characterize these systems. Our methodology can more generally be applied to identify the contributions of different processes involved in carving a channel network. In particular, we are able to identify transitions from fluvial to glaciated landscapes or vice versa.

Published
2017

Catalog

Books, media, physical & digital resources
See catalog results