Pyroclastic Activity at Home Plate in Gusev Crater, Mars

Squyres, S. W.; Aharonson, O.; Clark, B. C.; Cohen, B. A.; Crumpler, L. S.; Souza, P. A. de; Farrand, W. H.; Gellert, R.; Grotzinger, J. P.; Haldemann, A. F. C.; Johnson, J. R.; Klingelhöfer, G.; Lewis, K. W.; Li, R.; McCoy, Timothy J.; McEwen, A. S.; McSween, H. Y.; Ming, D. W.; Moore, Jeffrey M.; Morris, R. V.; Parker, T. J.; Rice, J. W.; Ruff, Steven W.; Schmidt, M. E.; Schröder, Christian; Soderblom, L. A.; Yen, A. S.

doi:10.1126/science.1139045

Cited by 180 publications

(220 citation statements)

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“…an understanding that the source of the amorphous component is debatable, based on the methodology developed here and the similarity in crystallinity and mineralogy between the Rocknest sand shadow sediment and the basaltic pyroclastic rocks of Gusev crater, we suggest that X-ray results are consistent with a relatively high proportion of basaltic glass indicating potentially widely distributed strombolian or plinian volcanic eruptive material on the surface of Mars 30,33 . This interpretation is consistent with the greater anticipated dispersal of explosive volcanic deposits on Mars 1 and prior observations regarding the widespread similarity between Martian soil and sediment 33 .…”

Section: Discussionmentioning

confidence: 50%

“…In contrast, Mössbauer spectroscopy results indicate a high proportion (27-29%) of npOx (absent from the Mini-TES results), suggesting that npOx may appear spectrally similar to basaltic glass using Mini-TES 30 . However, from the assumption that amorphous npOx is primarily derived from basaltic glass, the proportion of npOx may provide a means of estimating primary glass content even in severely altered volcanic rocks.…”

Section: Discussionmentioning

confidence: 53%

“…However, from the assumption that amorphous npOx is primarily derived from basaltic glass, the proportion of npOx may provide a means of estimating primary glass content even in severely altered volcanic rocks. A C wr of 55-80% from Mini-TES analysis of pyroclastic rocks in Gusev crater is consistent with a strombolian or plinian 'magmatic' eruption style, based on our methodology, rather than water/ice-driven phreatomagmatism 30,34 . However, high proportions of secondary silicate phases (up to B25%) identified in some of the Home Plate mini-TES results may imply severe alteration and an underestimation of the glass content.…”

Section: Discussionmentioning

confidence: 79%

“…The cooling rate of small (o1 cm) erupted particles therefore is controlled by the cooling rate of the eruption plume they are in equilibrium with. Numerical simulations of a near-vent gas thrust model transitioning to a convective plume 27,28 modified for Martian atmospheric pressure and temperature 29 , eruption velocities and vent diameters 1 , and magma composition 30 (Supplementary Table 1) are coupled with cooling ratecrystallization rate relationships above an estimated glass transition temperature of B730°C (refs. 18,31) to reconstruct syn-eruptive groundmass crystallization during plinian eruptions on Mars (see Supplementary Discussion 1 for details of numerical modelling).…”

Section: Discussionmentioning

confidence: 99%

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Determining volcanic eruption styles on Earth and Mars from crystallinity measurements

et al. 2014

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Both Earth and Mars possess different styles of explosive basaltic volcanism. Distinguishing phreatomagmatic eruptions, driven by magma-water interaction, from 'magmatic' explosive eruptions (that is, strombolian and plinian eruptions) is important for determining the presence of near-surface water or ice at the time of volcanism. Here we show that eruption styles can be broadly identified by relative variations in groundmass or bulk crystallinity determined by X-ray diffraction. Terrestrial analogue results indicate that rapidly quenched phreatomagmatic ejecta display lower groundmass crystallinity (o35%) than slower cooling ejecta from strombolian or plinian eruptions (440%). Numerical modelling suggests Martian plinian eruptive plumes moderate cooling, allowing 20-30% syn-eruptive crystallization, and thus reduce the distinction between eruption styles on Mars. Analysis of Mars Curiosity rover CheMin X-ray diffraction results from Gale crater indicate that the crystallinity of Martian sediment (52-54%) is similar to pyroclastic rocks from Gusev crater, Mars, and consistent with widespread distribution of basaltic strombolian or plinian volcanic ejecta.

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Section: Discussionmentioning

confidence: 50%

Section: Discussionmentioning

confidence: 53%

Section: Discussionmentioning

confidence: 79%

Section: Discussionmentioning

confidence: 99%

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Determining volcanic eruption styles on Earth and Mars from crystallinity measurements

et al. 2014

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“…Deposits in outcrops and soils in Gusev's Columbia Hills are interpreted as hydrothermal because of elevated silica and Ti (likely a sinter or leached deposit) and high S, Cl, and Br concentrations often associated with hydrothermal fluids (Squyres et al, 2007;Schmidt et al, 2008;Yen et al, 2008). The presence of Fe-sulfate minerals and partitioning between Cl and S suggest saline-acidic hydrothermal fluids (Squyres et al, 2007(Squyres et al, , 2008, potentially fumaroles (Squyres et al, 2007;Schmidt et al, 2009) or warm liquids (Squyres et al, 2008). Water-rock interaction explains the transport of non-volatile elements (e.g.…”

Section: Background: Mars Hydrothermal Alterationmentioning

confidence: 99%

Lassen Volcanic Fumaroles and Hot Springs: Analog for Mars

McHenry

Gerard

Walters

2014

Proc. Wisc. Space Conf.

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We are conducting a pilot study on the hydrothermal alteration of lavas at Lassen Volcanic National Park as an analog for potential hydrothermal deposits on Mars. Lassen has hot springs and fumaroles that have altered its lavas into silica, sulfates, and phyllosilicates, all mineral types also identified on Mars. Hydrothermal environments were likely common on Mars (due to evidence of early aqueous and a long record of volcanic activity), and such environments could have remained habitable long after the surface cooled and desiccated. However, some hydrothermal environments are more habitable than others, and being able to distinguish between the deposits of hostile acid-sulfate fumarole and more accommodating near-neutral hot spring environments can provide clues to habitability. Lassen hydrothermal environments produce silica by both acid-sulfate leaching and precipitation from neutral hydrothermal waters, both of which have been suggested as potential origins for deposits in Columbia Hills of Gusev Crater on Mars. ObjectivesThe objectives of this study are to:1. Determine the mineralogical and geochemical patterns of lava alteration associated with acid-sulfate leaching at Lassen hot springs and fumaroles, and contrast them with the patterns associated with more neutral, Cl-rich hydrothermal fluids at fumaroles and hot springs within Lassen park. 2. Compare these results to the mineralogy and geochemistry of hydrothermal deposits observed in the Columbia Hills of Gusev Crater, and determine if either scenario is more consistent with the observations. 3. Determine what mineralogical and geochemical evidence for hydrothermal alteration is most likely to be preserved in the rock record by analyzing samples from the hydrothermally altered lavas of Pleistocene Brokeoff Volcano (in Lassen park) and comparing them to samples from the active fields.

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Occurrence and origin of rhythmic sedimentary rocks on Mars

Lewis

Aharonson

2014

JGR Planets

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Sedimentary rocks preserved on the surface of Mars represent a natural archive of past climate conditions. Although the details of their formation often remain poorly constrained, the recent detection of rhythmic bedding patterns in the Arabia Terra region suggests the influence of orbital variations on sedimentary deposition. Here we detail a number of new sites which exhibit quasiperiodic stratigraphic variations, demonstrating their occurrence throughout the equatorial region of the planet. We characterize these recorded signals as well as the local geomorphic context and structural attributes. Two cyclic units are identified within Gale crater, the landing site of the Mars Science Laboratory mission, enabling estimation of possible formation timescales for the geologic units that may be studied in situ by the rover. We find a general lack of fluvial features in connection with rhythmic geologic units, contrasting these sites with the aperiodic deltaic stratigraphy found at Eberswalde crater. Possible formation scenarios and their climatic implications are discussed for the diverse set of quasiperiodic sedimentary units. We propose multiple depositional pathways for recording cyclic climate changes, including repeated evaporitic precipitation from groundwater discharge in topographic lows as well as largely anhydrous accumulation of atmospheric dust for deposits outside of confined basins. The preservation of orbital signals in sediments distributed across a wide range of geographic settings suggests a pervasive influence on Martian climate conditions through time.

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Pyroclastic Activity at Home Plate in Gusev Crater, Mars

Cited by 180 publications

References 14 publications

Determining volcanic eruption styles on Earth and Mars from crystallinity measurements

Determining volcanic eruption styles on Earth and Mars from crystallinity measurements

Lassen Volcanic Fumaroles and Hot Springs: Analog for Mars

Occurrence and origin of rhythmic sedimentary rocks on Mars

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