Landslides on Ceres: Diversity and Geologic Context

Landslides on Ceres: Diversity and Geologic Context

Landslides are among the most widespread geologic features on Ceres. Using data from Dawn's Framing Camera, landslides were previously classified based upon geomorphologic characteristics into one of three archetypal categories, Type 1(T1), Type 2 (T2), and Type 3 (T3). Due to their geologic co...

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Veröffentlicht in:Journal of geophysical research. Planets 2019-12, Vol.124 (12), p.3329-3343
Hauptverfasser: Duarte, K. D., Schmidt, B. E., Chilton, H. T., Hughson, K. H. G., Sizemore, H. G., Ferrier, K. L., Buffo, J. J., Scully, J. E. C., Nathues, A., Platz, T., Landis, M., Byrne, S., Bland, M., Russell, C. T., Raymond, C. A.
Format: Artikel
Sprache:eng
Schlagworte:
Asteroids
Ceres
Craters
Ejecta
Framing cameras
Geology
Geomorphology
Ground ice
Ice
Ice on Ceres
Ices
Landslides
Landslides & mudslides
Mechanical properties
Morphology
Natural Hazards
Other
Physical properties
Planetary Sciences: Solar System Objects
Planetary Sciences: Solid Surface Planets
Slumping
Tectonics and Landscape Evolution
Tectonophysics
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container_end_page 3343
container_issue 12
container_start_page 3329
container_title Journal of geophysical research. Planets
container_volume 124
creator Duarte, K. D.
Schmidt, B. E.
Chilton, H. T.
Hughson, K. H. G.
Sizemore, H. G.
Ferrier, K. L.
Buffo, J. J.
Scully, J. E. C.
Nathues, A.
Platz, T.
Landis, M.
Byrne, S.
Bland, M.
Russell, C. T.
Raymond, C. A.
description Landslides are among the most widespread geologic features on Ceres. Using data from Dawn's Framing Camera, landslides were previously classified based upon geomorphologic characteristics into one of three archetypal categories, Type 1(T1), Type 2 (T2), and Type 3 (T3). Due to their geologic context, variation in age, and physical characteristics, most landslides on Ceres are, however, intermediate in their morphology and physical properties between the archetypes of each landslide class. Here we describe the varied morphology of individual intermediate landslides, identify geologic controls that contribute to this variation, and provide first‐order quantification of the physical properties of the continuum of Ceres's surface flows. These intermediate flows appear in varied settings and show a range of characteristics, including those found at contacts between craters, those having multiple trunks or lobes; showing characteristics of both T2 and T3 landslides; material slumping on crater rims; very small, ejecta‐like flows; and those appearing inside of catenae. We suggest that while their morphologies can vary, the distribution and mechanical properties of intermediate landslides do not differ significantly from that of archetypal landslides, confirming a link between landslides and subsurface ice. We also find that most intermediate landslides are similar to Type 2 landslides and formed by shallow failure. Clusters of these features suggest ice enhancement near Juling, Kupalo and Urvara craters. Since the majority of Ceres's landslides fall in the intermediate landslide category, placing their attributes in context contributes to a better understanding of Ceres's shallow subsurface and the nature of ground ice. Plain Language Summary Previously, three distinct types of landslides on Ceres, Type 1 (T1), Type 2 (T2), and Type 3 (T3), were identified and classified by their shapes and locations, but most landslides on Ceres do not fall cleanly into those categories based on shape alone. We have analyzed these intermediate landslides to further describe the continuum of flows seen on Ceres. Here, we study their intrinsic properties to gain a greater understanding of Ceres's subsurface properties. Overall, the locations, shapes, and properties of these landslides on Ceres appear to be influenced by ice contained within Ceres's surface and subsurface materials and suggest local ice enhancement is present in some regions, such as near Juling, Kupalo, and Urvara
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D. ; Schmidt, B. E. ; Chilton, H. T. ; Hughson, K. H. G. ; Sizemore, H. G. ; Ferrier, K. L. ; Buffo, J. J. ; Scully, J. E. C. ; Nathues, A. ; Platz, T. ; Landis, M. ; Byrne, S. ; Bland, M. ; Russell, C. T. ; Raymond, C. A.</creator><creatorcontrib>Duarte, K. D. ; Schmidt, B. E. ; Chilton, H. T. ; Hughson, K. H. G. ; Sizemore, H. G. ; Ferrier, K. L. ; Buffo, J. J. ; Scully, J. E. C. ; Nathues, A. ; Platz, T. ; Landis, M. ; Byrne, S. ; Bland, M. ; Russell, C. T. ; Raymond, C. A.</creatorcontrib><description>Landslides are among the most widespread geologic features on Ceres. Using data from Dawn's Framing Camera, landslides were previously classified based upon geomorphologic characteristics into one of three archetypal categories, Type 1(T1), Type 2 (T2), and Type 3 (T3). Due to their geologic context, variation in age, and physical characteristics, most landslides on Ceres are, however, intermediate in their morphology and physical properties between the archetypes of each landslide class. Here we describe the varied morphology of individual intermediate landslides, identify geologic controls that contribute to this variation, and provide first‐order quantification of the physical properties of the continuum of Ceres's surface flows. These intermediate flows appear in varied settings and show a range of characteristics, including those found at contacts between craters, those having multiple trunks or lobes; showing characteristics of both T2 and T3 landslides; material slumping on crater rims; very small, ejecta‐like flows; and those appearing inside of catenae. We suggest that while their morphologies can vary, the distribution and mechanical properties of intermediate landslides do not differ significantly from that of archetypal landslides, confirming a link between landslides and subsurface ice. We also find that most intermediate landslides are similar to Type 2 landslides and formed by shallow failure. Clusters of these features suggest ice enhancement near Juling, Kupalo and Urvara craters. Since the majority of Ceres's landslides fall in the intermediate landslide category, placing their attributes in context contributes to a better understanding of Ceres's shallow subsurface and the nature of ground ice. Plain Language Summary Previously, three distinct types of landslides on Ceres, Type 1 (T1), Type 2 (T2), and Type 3 (T3), were identified and classified by their shapes and locations, but most landslides on Ceres do not fall cleanly into those categories based on shape alone. We have analyzed these intermediate landslides to further describe the continuum of flows seen on Ceres. Here, we study their intrinsic properties to gain a greater understanding of Ceres's subsurface properties. Overall, the locations, shapes, and properties of these landslides on Ceres appear to be influenced by ice contained within Ceres's surface and subsurface materials and suggest local ice enhancement is present in some regions, such as near Juling, Kupalo, and Urvara craters. Key Points Landslides on Ceres have a wide range of morphologies Subsurface ice affects the formation of most landslides on Ceres and influences their morphology Ceres has widespread ground ice with ice enhancements near the poles and within Juling and Kupalo craters</description><identifier>ISSN: 2169-9097</identifier><identifier>EISSN: 2169-9100</identifier><identifier>DOI: 10.1029/2018JE005673</identifier><identifier>PMID: 32355585</identifier><language>eng</language><publisher>United States: Blackwell Publishing Ltd</publisher><subject>Asteroids ; Ceres ; Craters ; Ejecta ; Framing cameras ; Geology ; Geomorphology ; Ground ice ; Ice ; Ice on Ceres ; Ices ; Landslides ; Landslides &amp; mudslides ; Mechanical properties ; Morphology ; Natural Hazards ; Other ; Physical properties ; Planetary Sciences: Solar System Objects ; Planetary Sciences: Solid Surface Planets ; Slumping ; Tectonics and Landscape Evolution ; Tectonophysics</subject><ispartof>Journal of geophysical research. 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D.</creatorcontrib><creatorcontrib>Schmidt, B. E.</creatorcontrib><creatorcontrib>Chilton, H. T.</creatorcontrib><creatorcontrib>Hughson, K. H. G.</creatorcontrib><creatorcontrib>Sizemore, H. G.</creatorcontrib><creatorcontrib>Ferrier, K. L.</creatorcontrib><creatorcontrib>Buffo, J. J.</creatorcontrib><creatorcontrib>Scully, J. E. C.</creatorcontrib><creatorcontrib>Nathues, A.</creatorcontrib><creatorcontrib>Platz, T.</creatorcontrib><creatorcontrib>Landis, M.</creatorcontrib><creatorcontrib>Byrne, S.</creatorcontrib><creatorcontrib>Bland, M.</creatorcontrib><creatorcontrib>Russell, C. T.</creatorcontrib><creatorcontrib>Raymond, C. A.</creatorcontrib><title>Landslides on Ceres: Diversity and Geologic Context</title><title>Journal of geophysical research. Planets</title><addtitle>J Geophys Res Planets</addtitle><description>Landslides are among the most widespread geologic features on Ceres. Using data from Dawn's Framing Camera, landslides were previously classified based upon geomorphologic characteristics into one of three archetypal categories, Type 1(T1), Type 2 (T2), and Type 3 (T3). Due to their geologic context, variation in age, and physical characteristics, most landslides on Ceres are, however, intermediate in their morphology and physical properties between the archetypes of each landslide class. Here we describe the varied morphology of individual intermediate landslides, identify geologic controls that contribute to this variation, and provide first‐order quantification of the physical properties of the continuum of Ceres's surface flows. These intermediate flows appear in varied settings and show a range of characteristics, including those found at contacts between craters, those having multiple trunks or lobes; showing characteristics of both T2 and T3 landslides; material slumping on crater rims; very small, ejecta‐like flows; and those appearing inside of catenae. We suggest that while their morphologies can vary, the distribution and mechanical properties of intermediate landslides do not differ significantly from that of archetypal landslides, confirming a link between landslides and subsurface ice. We also find that most intermediate landslides are similar to Type 2 landslides and formed by shallow failure. Clusters of these features suggest ice enhancement near Juling, Kupalo and Urvara craters. Since the majority of Ceres's landslides fall in the intermediate landslide category, placing their attributes in context contributes to a better understanding of Ceres's shallow subsurface and the nature of ground ice. Plain Language Summary Previously, three distinct types of landslides on Ceres, Type 1 (T1), Type 2 (T2), and Type 3 (T3), were identified and classified by their shapes and locations, but most landslides on Ceres do not fall cleanly into those categories based on shape alone. We have analyzed these intermediate landslides to further describe the continuum of flows seen on Ceres. Here, we study their intrinsic properties to gain a greater understanding of Ceres's subsurface properties. Overall, the locations, shapes, and properties of these landslides on Ceres appear to be influenced by ice contained within Ceres's surface and subsurface materials and suggest local ice enhancement is present in some regions, such as near Juling, Kupalo, and Urvara craters. 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D. ; Schmidt, B. E. ; Chilton, H. T. ; Hughson, K. H. G. ; Sizemore, H. G. ; Ferrier, K. L. ; Buffo, J. J. ; Scully, J. E. C. ; Nathues, A. ; Platz, T. ; Landis, M. ; Byrne, S. ; Bland, M. ; Russell, C. T. ; Raymond, C. 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C.</au><au>Nathues, A.</au><au>Platz, T.</au><au>Landis, M.</au><au>Byrne, S.</au><au>Bland, M.</au><au>Russell, C. T.</au><au>Raymond, C. A.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Landslides on Ceres: Diversity and Geologic Context</atitle><jtitle>Journal of geophysical research. Planets</jtitle><addtitle>J Geophys Res Planets</addtitle><date>2019-12</date><risdate>2019</risdate><volume>124</volume><issue>12</issue><spage>3329</spage><epage>3343</epage><pages>3329-3343</pages><issn>2169-9097</issn><eissn>2169-9100</eissn><abstract>Landslides are among the most widespread geologic features on Ceres. Using data from Dawn's Framing Camera, landslides were previously classified based upon geomorphologic characteristics into one of three archetypal categories, Type 1(T1), Type 2 (T2), and Type 3 (T3). Due to their geologic context, variation in age, and physical characteristics, most landslides on Ceres are, however, intermediate in their morphology and physical properties between the archetypes of each landslide class. Here we describe the varied morphology of individual intermediate landslides, identify geologic controls that contribute to this variation, and provide first‐order quantification of the physical properties of the continuum of Ceres's surface flows. These intermediate flows appear in varied settings and show a range of characteristics, including those found at contacts between craters, those having multiple trunks or lobes; showing characteristics of both T2 and T3 landslides; material slumping on crater rims; very small, ejecta‐like flows; and those appearing inside of catenae. We suggest that while their morphologies can vary, the distribution and mechanical properties of intermediate landslides do not differ significantly from that of archetypal landslides, confirming a link between landslides and subsurface ice. We also find that most intermediate landslides are similar to Type 2 landslides and formed by shallow failure. Clusters of these features suggest ice enhancement near Juling, Kupalo and Urvara craters. Since the majority of Ceres's landslides fall in the intermediate landslide category, placing their attributes in context contributes to a better understanding of Ceres's shallow subsurface and the nature of ground ice. Plain Language Summary Previously, three distinct types of landslides on Ceres, Type 1 (T1), Type 2 (T2), and Type 3 (T3), were identified and classified by their shapes and locations, but most landslides on Ceres do not fall cleanly into those categories based on shape alone. We have analyzed these intermediate landslides to further describe the continuum of flows seen on Ceres. Here, we study their intrinsic properties to gain a greater understanding of Ceres's subsurface properties. Overall, the locations, shapes, and properties of these landslides on Ceres appear to be influenced by ice contained within Ceres's surface and subsurface materials and suggest local ice enhancement is present in some regions, such as near Juling, Kupalo, and Urvara craters. 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ispartof Journal of geophysical research. Planets, 2019-12, Vol.124 (12), p.3329-3343
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language eng
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source Wiley Online Library Journals Frontfile Complete; Wiley Online Library Free Content; Alma/SFX Local Collection
subjects Asteroids
Ceres
Craters
Ejecta
Framing cameras
Geology
Geomorphology
Ground ice
Ice
Ice on Ceres
Ices
Landslides
Landslides & mudslides
Mechanical properties
Morphology
Natural Hazards
Other
Physical properties
Planetary Sciences: Solar System Objects
Planetary Sciences: Solid Surface Planets
Slumping
Tectonics and Landscape Evolution
Tectonophysics
title Landslides on Ceres: Diversity and Geologic Context
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