Geomorphology reveals active décollement geometry in the central Himalayan seismic gap
The ∼700-km-long "central seismic gap" is the most prominent segment of the Himalayan front not to have ruptured in a major earthquake during the last 200-500 yr. This prolonged seismic quiescence has led to the proposition that this region, with a population >10 million, is overdue for...
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| Veröffentlicht in: | Lithosphere 2015-06, Vol.7 (3), p.247-256 |
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| creator | Morell, Kristin D Sandiford, Mike Rajendran, C. P Rajendran, Kusala Alimanovic, Abaz Fink, David Sanwal, Jaishri |
| description | The ∼700-km-long "central seismic gap" is the most prominent segment of the Himalayan front not to have ruptured in a major earthquake during the last 200-500 yr. This prolonged seismic quiescence has led to the proposition that this region, with a population >10 million, is overdue for a great earthquake. Despite the region's recognized seismic risk, the geometry of faults likely to host large earthquakes remains poorly understood. Here, we place new constraints on the spatial distribution of rock uplift within the western ∼400 km of the central seismic gap using topographic and river profile analyses together with basinwide erosion rate estimates from cosmogenic 10Be. The data sets show a distinctive physiographic transition at the base of the high Himalaya in the state of Uttarakhand, India, characterized by abrupt strike-normal increases in channel steepness and a tenfold increase in erosion rates. When combined with previously published geophysical imaging and seismicity data sets, we interpret the observed spatial distribution of erosion rates and channel steepness to reflect the landscape response to spatially variable rock uplift due to a structurally coherent ramp-flat system of the Main Himalayan Thrust. Although it remains unresolved whether the kinematics of the Main Himalayan Thrust ramp involve an emergent fault or duplex, the landscape and erosion rate patterns suggest that the decollement beneath the state of Uttarakhand provides a sufficiently large and coherent fault segment capable of hosting a great earthquake. |
| doi_str_mv | 10.1130/L407.1 |
| format | Article |
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P ; Rajendran, Kusala ; Alimanovic, Abaz ; Fink, David ; Sanwal, Jaishri</creator><creatorcontrib>Morell, Kristin D ; Sandiford, Mike ; Rajendran, C. P ; Rajendran, Kusala ; Alimanovic, Abaz ; Fink, David ; Sanwal, Jaishri</creatorcontrib><description>The ∼700-km-long "central seismic gap" is the most prominent segment of the Himalayan front not to have ruptured in a major earthquake during the last 200-500 yr. This prolonged seismic quiescence has led to the proposition that this region, with a population >10 million, is overdue for a great earthquake. Despite the region's recognized seismic risk, the geometry of faults likely to host large earthquakes remains poorly understood. Here, we place new constraints on the spatial distribution of rock uplift within the western ∼400 km of the central seismic gap using topographic and river profile analyses together with basinwide erosion rate estimates from cosmogenic 10Be. The data sets show a distinctive physiographic transition at the base of the high Himalaya in the state of Uttarakhand, India, characterized by abrupt strike-normal increases in channel steepness and a tenfold increase in erosion rates. When combined with previously published geophysical imaging and seismicity data sets, we interpret the observed spatial distribution of erosion rates and channel steepness to reflect the landscape response to spatially variable rock uplift due to a structurally coherent ramp-flat system of the Main Himalayan Thrust. Although it remains unresolved whether the kinematics of the Main Himalayan Thrust ramp involve an emergent fault or duplex, the landscape and erosion rate patterns suggest that the decollement beneath the state of Uttarakhand provides a sufficiently large and coherent fault segment capable of hosting a great earthquake.</description><identifier>ISSN: 1941-8264</identifier><identifier>EISSN: 1947-4253</identifier><identifier>DOI: 10.1130/L407.1</identifier><language>eng</language><publisher>Geological Society of America</publisher><subject>Alaknanda River basin ; alkaline earth metals ; Asia ; ASTER data ; atmospheric precipitation ; Be-10 ; beryllium ; Bhagirathi River ; Cenozoic ; channels ; decollement ; elevation ; erosion ; erosion rates ; fluvial features ; geometry ; geomorphology ; Himalayas ; Holocene ; hydrology ; India ; Indian Peninsula ; isotopes ; Kali River basin ; landform evolution ; landscapes ; lithosphere ; Main Himalayan Thrust ; metals ; modern ; neotectonics ; Quaternary ; radar methods ; radioactive isotopes ; rainfall ; relief ; rivers ; seismic gaps ; seismic quiescence ; seismic risk ; seismicity ; Seismology ; Shuttle Radar Topography Mission ; slopes ; SRTM data ; tectonics ; topography ; uplifts ; upper Holocene ; Uttarakhand India</subject><ispartof>Lithosphere, 2015-06, Vol.7 (3), p.247-256</ispartof><rights>GeoRef, Copyright 2022, American Geosciences Institute. 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Here, we place new constraints on the spatial distribution of rock uplift within the western ∼400 km of the central seismic gap using topographic and river profile analyses together with basinwide erosion rate estimates from cosmogenic 10Be. The data sets show a distinctive physiographic transition at the base of the high Himalaya in the state of Uttarakhand, India, characterized by abrupt strike-normal increases in channel steepness and a tenfold increase in erosion rates. When combined with previously published geophysical imaging and seismicity data sets, we interpret the observed spatial distribution of erosion rates and channel steepness to reflect the landscape response to spatially variable rock uplift due to a structurally coherent ramp-flat system of the Main Himalayan Thrust. Although it remains unresolved whether the kinematics of the Main Himalayan Thrust ramp involve an emergent fault or duplex, the landscape and erosion rate patterns suggest that the decollement beneath the state of Uttarakhand provides a sufficiently large and coherent fault segment capable of hosting a great earthquake.</description><subject>Alaknanda River basin</subject><subject>alkaline earth metals</subject><subject>Asia</subject><subject>ASTER data</subject><subject>atmospheric precipitation</subject><subject>Be-10</subject><subject>beryllium</subject><subject>Bhagirathi River</subject><subject>Cenozoic</subject><subject>channels</subject><subject>decollement</subject><subject>elevation</subject><subject>erosion</subject><subject>erosion rates</subject><subject>fluvial features</subject><subject>geometry</subject><subject>geomorphology</subject><subject>Himalayas</subject><subject>Holocene</subject><subject>hydrology</subject><subject>India</subject><subject>Indian Peninsula</subject><subject>isotopes</subject><subject>Kali River basin</subject><subject>landform evolution</subject><subject>landscapes</subject><subject>lithosphere</subject><subject>Main Himalayan Thrust</subject><subject>metals</subject><subject>modern</subject><subject>neotectonics</subject><subject>Quaternary</subject><subject>radar methods</subject><subject>radioactive isotopes</subject><subject>rainfall</subject><subject>relief</subject><subject>rivers</subject><subject>seismic gaps</subject><subject>seismic quiescence</subject><subject>seismic risk</subject><subject>seismicity</subject><subject>Seismology</subject><subject>Shuttle Radar Topography Mission</subject><subject>slopes</subject><subject>SRTM data</subject><subject>tectonics</subject><subject>topography</subject><subject>uplifts</subject><subject>upper Holocene</subject><subject>Uttarakhand India</subject><issn>1941-8264</issn><issn>1947-4253</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2015</creationdate><recordtype>article</recordtype><recordid>eNotkEFOwzAQRS0EEqXAGbxig1I8thMnS1RBixSJDYil5TiTNlUSV3YoypE4BxfDpaxmNHr6evMJuQW2ABDsoZRMLeCMzKCQKpE8Fed_OyQ5z-QluQphx1iWKaVm5GOFrnd-v3Wd20zU4wFNF6ixY3tAWv98W9d12OMw0k0kcfQTbQc6bpHaePSmo-u2N52ZzEADtqFvLd2Y_TW5aGIQ3vzPOXl_fnpbrpPydfWyfCwTI3I2JrICAwxVzRkgskpYyGoO1hYmLVSjlFQVyy0KnmeQc6gqBFOlpmgqKQRaMSd3p1zrXQgeG7330cdPGpg-1qGPdWiI4P0JjG8E2-Jg8cv5rtY79-mHqKijQqqZ4EJI8QuB7GLC</recordid><startdate>20150601</startdate><enddate>20150601</enddate><creator>Morell, Kristin D</creator><creator>Sandiford, Mike</creator><creator>Rajendran, C. P</creator><creator>Rajendran, Kusala</creator><creator>Alimanovic, Abaz</creator><creator>Fink, David</creator><creator>Sanwal, Jaishri</creator><general>Geological Society of America</general><scope>AAYXX</scope><scope>CITATION</scope></search><sort><creationdate>20150601</creationdate><title>Geomorphology reveals active décollement geometry in the central Himalayan seismic gap</title><author>Morell, Kristin D ; Sandiford, Mike ; Rajendran, C. P ; Rajendran, Kusala ; Alimanovic, Abaz ; Fink, David ; Sanwal, Jaishri</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a380t-4b1a10e7d201ee0b3c16d21cc9a597f7747b08ce32861821bbe1ab5a9fb433ec3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2015</creationdate><topic>Alaknanda River basin</topic><topic>alkaline earth metals</topic><topic>Asia</topic><topic>ASTER data</topic><topic>atmospheric precipitation</topic><topic>Be-10</topic><topic>beryllium</topic><topic>Bhagirathi River</topic><topic>Cenozoic</topic><topic>channels</topic><topic>decollement</topic><topic>elevation</topic><topic>erosion</topic><topic>erosion rates</topic><topic>fluvial features</topic><topic>geometry</topic><topic>geomorphology</topic><topic>Himalayas</topic><topic>Holocene</topic><topic>hydrology</topic><topic>India</topic><topic>Indian Peninsula</topic><topic>isotopes</topic><topic>Kali River basin</topic><topic>landform evolution</topic><topic>landscapes</topic><topic>lithosphere</topic><topic>Main Himalayan Thrust</topic><topic>metals</topic><topic>modern</topic><topic>neotectonics</topic><topic>Quaternary</topic><topic>radar methods</topic><topic>radioactive isotopes</topic><topic>rainfall</topic><topic>relief</topic><topic>rivers</topic><topic>seismic gaps</topic><topic>seismic quiescence</topic><topic>seismic risk</topic><topic>seismicity</topic><topic>Seismology</topic><topic>Shuttle Radar Topography Mission</topic><topic>slopes</topic><topic>SRTM data</topic><topic>tectonics</topic><topic>topography</topic><topic>uplifts</topic><topic>upper Holocene</topic><topic>Uttarakhand India</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Morell, Kristin D</creatorcontrib><creatorcontrib>Sandiford, Mike</creatorcontrib><creatorcontrib>Rajendran, C. P</creatorcontrib><creatorcontrib>Rajendran, Kusala</creatorcontrib><creatorcontrib>Alimanovic, Abaz</creatorcontrib><creatorcontrib>Fink, David</creatorcontrib><creatorcontrib>Sanwal, Jaishri</creatorcontrib><collection>CrossRef</collection><jtitle>Lithosphere</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Morell, Kristin D</au><au>Sandiford, Mike</au><au>Rajendran, C. P</au><au>Rajendran, Kusala</au><au>Alimanovic, Abaz</au><au>Fink, David</au><au>Sanwal, Jaishri</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Geomorphology reveals active décollement geometry in the central Himalayan seismic gap</atitle><jtitle>Lithosphere</jtitle><date>2015-06-01</date><risdate>2015</risdate><volume>7</volume><issue>3</issue><spage>247</spage><epage>256</epage><pages>247-256</pages><issn>1941-8264</issn><eissn>1947-4253</eissn><abstract>The ∼700-km-long "central seismic gap" is the most prominent segment of the Himalayan front not to have ruptured in a major earthquake during the last 200-500 yr. This prolonged seismic quiescence has led to the proposition that this region, with a population >10 million, is overdue for a great earthquake. Despite the region's recognized seismic risk, the geometry of faults likely to host large earthquakes remains poorly understood. Here, we place new constraints on the spatial distribution of rock uplift within the western ∼400 km of the central seismic gap using topographic and river profile analyses together with basinwide erosion rate estimates from cosmogenic 10Be. The data sets show a distinctive physiographic transition at the base of the high Himalaya in the state of Uttarakhand, India, characterized by abrupt strike-normal increases in channel steepness and a tenfold increase in erosion rates. When combined with previously published geophysical imaging and seismicity data sets, we interpret the observed spatial distribution of erosion rates and channel steepness to reflect the landscape response to spatially variable rock uplift due to a structurally coherent ramp-flat system of the Main Himalayan Thrust. Although it remains unresolved whether the kinematics of the Main Himalayan Thrust ramp involve an emergent fault or duplex, the landscape and erosion rate patterns suggest that the decollement beneath the state of Uttarakhand provides a sufficiently large and coherent fault segment capable of hosting a great earthquake.</abstract><pub>Geological Society of America</pub><doi>10.1130/L407.1</doi><tpages>10</tpages><oa>free_for_read</oa></addata></record> |
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| subjects | Alaknanda River basin alkaline earth metals Asia ASTER data atmospheric precipitation Be-10 beryllium Bhagirathi River Cenozoic channels decollement elevation erosion erosion rates fluvial features geometry geomorphology Himalayas Holocene hydrology India Indian Peninsula isotopes Kali River basin landform evolution landscapes lithosphere Main Himalayan Thrust metals modern neotectonics Quaternary radar methods radioactive isotopes rainfall relief rivers seismic gaps seismic quiescence seismic risk seismicity Seismology Shuttle Radar Topography Mission slopes SRTM data tectonics topography uplifts upper Holocene Uttarakhand India |
| title | Geomorphology reveals active décollement geometry in the central Himalayan seismic gap |
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