5 results on '"Grau Galofre, A."'
Search Results
2. Patterns of martian glacial deformation: Implications for glacio-geology, internal structure, and regional climate.
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Grau Galofre, Anna, Serla, Jayanth K., Becerra, Patricio, Noblet, Axel, and Conway, Susan J.
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HIGH resolution imaging , *DEFORMATIONS (Mechanics) , *VISCOUS flow , *LASER altimeters , *IMAGING systems , *ABLATION (Glaciology) - Abstract
Viscous Flow Features (VFF) are widespread in the martian mid-latitudes and indicative of near-surface ice deposits. Their distribution and morphology hint at the regional history of ice deposition and ablation, as well as changes in surface temperature. Here we interrogate the deformation history of a type of VFF, a Lobate Debris Apron (LDA), located in the eastern Hellas region, from its surface morphology, discussing the implications it poses for its internal structure and regional climate variability. Our observations integrate data from the Colour and Stereo Surface Imaging System (CaSSIS), the SHAllow RADar (SHARAD), the Context Camera (CTX), the High Resolution Imaging Science Experiment (HiRISE), and the Mars Orbiter Laser Altimeter (MOLA). Morphological observations, spectral analysis of characteristic wavelengths, and ice deformation stability analysis place constraints on the dynamics and deformation history of the deposit. We discuss contrasting hypotheses for the origin of the different surface structures, including the possibility of gelifluction in addition to glacial creep. Our results provide a guide to interpret glacial deformation patterns in martian VFFs in the light of internal structure, regional climate history, and underlying topography. [Display omitted] • Glacial deformation patterns are linked to climate and external forcing. • Mid-latitude martian glacial landscape evolution can hold climate record. • Lobate Debris Aprons (LDA) history from its deformational morphology. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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3. Did Martian valley networks substantially modify the landscape?
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Grau Galofre, Anna, Bahia, Rickbir Singh, Jellinek, A. Mark, Whipple, Kelin X., and Gallo, Rose
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VALLEYS , *HYDROLOGY , *TOPOGRAPHY - Abstract
• Most Martian valleys failed to fluvially erode the landscape and reach steady-state. • Rain/snow and evaporation/sublimation dominated Martian drainage basin hydrology. • Six valley networks analyzed, e.g., Naktong and Evros valles, reached steady-state. 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. [ABSTRACT FROM AUTHOR]
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- 2020
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4. CanMars mission Science Team operational results: Implications for operations and the sample selection process for Mars Sample Return (MSR).
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Caudill, Christy M., Pontefract, Alexandra J., Osinski, Gordon R., Tornabene, Livio L., Pilles, Eric A., Battler, Melissa, Francis, Raymond, Godin, Etienne, Grau Galofre, Anna, Haltigin, Timothy, Hipkin, Victoria J., Mittelholz, Anna, Poitras, Jordan, Simpson, Sarah L., Svensson, Matthew, Xie, Tianqi, and Morse, Zachary R.
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SAMPLING (Process) , *MARS (Planet) , *DRILLING & boring , *LABORATORIES , *OPERATIONS management , *WORKFLOW management , *TEAMS - 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. • Rover mission operations management, procedures, and workflows were vetted. • We document the complex Science Team interactions relevant to operational workflows. • An intentional operational structure must be employed for optimal use of very limited mission time. [ABSTRACT FROM AUTHOR]
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- 2019
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5. Insights into the interaction between defrosting seasonal ices and gully activity from CaSSIS and HiRISE observations in Sisyphi Cavi, Mars.
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Pasquon, K., Conway, S.J., Vincendon, M., Massé, M., Raack, J., Noblet, A., Grau Galofre, A., Morino, C., Munaretto, G., Lucchetti, A., Pajola, M., and Lewis, Stephen R.
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EPHEMERAL streams , *HIGH resolution imaging , *SEASONS , *MARS (Planet) , *SEDIMENTATION & deposition , *IMAGING systems , *SUBMARINE fans - Abstract
Martian gullies are surface features, typically composed of an alcove, a channel and a depositional apron. They have been extensively studied since their first observations in the 2000s and were initially attributed to the action of liquid water. Later studies highlighted that their activity is spatially and temporally correlated with the seasonal presence of surface CO 2 ice, suggesting a link between seasonal frost and gully activity. However, the exact mechanisms leading to gully formation are still under debate. Establishing whether or not gullies are formed by liquid water has important implications for Mars recent climate and habitability. Here, we study the evolution of seasonal frost and its connection to gully activity in Sisyphi Cavi, located in the southern circumpolar region (68°S - 74°S; 345°E − 5°E). The high latitude of this site allows for detailed temporal monitoring, owing to the high frequency imaging by spacecraft in polar orbits, largely unavailable for other martian gullies, hence this site has the potential to reveal new insights on gullies in general. In particular, we used repeat images from MRO HiRISE (Mars Reconnaissance Orbiter, High Resolution Imaging Science Experiment) and TGO CaSSIS (Trace Gas Orbiter, Colour and Stereo Surface Imaging System). Our findings show that the general timing and characteristics of the defrosting patterns in Sisyphi Cavi follow seasonal patterns that are consistent from year to year. The timing of the start of defrosting and its temporal evolution are controlled by the overall orientation of the host hillslope, with equator-facing slopes defrosting before pole-facing ones and the steepest pole-facing slopes defrosting last. Gully alcoves defrost before channels and aprons located on the same hillslope independent of the orientation of the hillslope likely because the aprons have a lower thermal inertia than the alcoves that counteracts the orientation effect, which on pole-facing slopes would mean the alcoves should defrost last. We observe the presence of seasonal and ephemeral dark spots and flows which are interpreted to be a result of sediment deposition on top of the seasonal ice deposits, triggered by basal sublimation. Our observations suggest that the appearance of dark spots and dark flows can be spatially correlated with surface roughness, including presence of boulders, contrasts in material types, irregular lobes/levees and braiding caused by gully activity, and therefore could be used to help detect recently active gullies on Mars in areas with seasonal frost without the need of repeat imaging. Finally, we propose that presently observed gully activity in Sisyphi Cavi is driven by defrosted material flowing on to a frosted apron. We infer that the presence of a frosted apron could be common precursor for this type gully activity. We note that this activity only involves the mobilisation of loose materials and we have not observed any erosion of the wall rock present in Sisyphi Cavi. [Display omitted] • We perform detailed monitoring of gullies and seasonal frosts in Sisyphi Cavi. • Gully alcoves defrost before their aprons even on pole-facing slopes. • Early alcove defrosting is likely related to their higher thermal inertia. • Frosted aprons are common on Mars and could be a precursor to gully activity. • Dark spots/flows found on rough terrain may highlight recently active gullies. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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