Crustal structure of the Central-Eastern Greenland: results from the Topo Greenland refraction profile

Until present, seismic surveys have only been carried out offshore and near the coasts of Greenland, where the crustal structure is affected by oceanic break-up. We present the deep seismic structure of the crust of the interior of Greenland, based on the new and the only existing so far seismic ref...

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Main Authors: Shulgin, Alexey, Thybo, Hans
Format: Conference Object
Language:English
Published: 2014
Subjects:
Greenland
Norway
Scoresby
Scoresby Sund
Sund
Ice cap
Ice Sheet
Iceland
North Atlantic
TopoGreenland
Online Access:https://curis.ku.dk/portal/da/publications/crustal-structure-of-the-centraleastern-greenland-results-from-the-topo-greenland-refraction-profile(99e8ba97-bd7e-413e-ac49-a17b11f786a2).html
http://meetingorganizer.copernicus.org/EGU2014/EGU2014-9008.pdf
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record_format openpolar
institution Open Polar
collection University of Copenhagen: Research
op_collection_id ftcopenhagenunip
language English
description Until present, seismic surveys have only been carried out offshore and near the coasts of Greenland, where the crustal structure is affected by oceanic break-up. We present the deep seismic structure of the crust of the interior of Greenland, based on the new and the only existing so far seismic refraction/wide-angle reflection profile. The seismic data was acquired by a team of six people during a two-month long experiment in summer of 2011 on the ice cap in the interior of central-eastern Greenland. The presence of an up to 3.4 km thick ice sheet, permanently covering most of the land mass, made acquisition of geophysical data logistically complicated. The profile extends 310 km inland in E-W direction from the approximate edge of the stable ice cap near the Scoresby Sund across the center of the ice cap. 350 Reftek Texan receivers recorded high-quality seismic data from 8 equidistant shots along the profile. Explosive charge sizes were 1 ton at the ends and ca. 500 kg along the profile, loaded with about 125 kg at 35-85 m depth in individual boreholes. Given that the data acquisition was affected by the thick ice sheet, we questioned the quality of seismic records in such experiment setup. We have developed an automatic routine to check the amplitudes and spectra of the selected seismic phases and to check the differences/challenges in making seismic experiments on ice and the effects of ice on data interpretation. Using tomographic inversion and forward ray tracing modelling we have obtained the two-dimensional velocity model down to a 50 km depth. The model shows a decrease of crustal thickness from 47 km below the centre of Greenland in the western part of the profile to 40 km in its eastern part. Relatively high lower crustal velocities (Vp 6.8 – 7.3 km/s) in the western part of the TopoGreenland profile may result from past collision tectonics or, alternatively, may be related to the speculated passage of the Iceland mantle plume. Comparison of our results with the new receiver function studies (Kraft et al., personal communication) suggests the possibility for a massive underplating along the profile. The origin of the pronounced circum-Atlantic mountain ranges in Norway and eastern Greenland, which have average elevation above 1500 m with peak elevations of more than 3.5 km near the Scoresby Sund in Eastern Greenland, is unknown. Our new results on the crustal structure provide constraints for assessment of the isostatic balance of the crust in Greenland, as well as for examining possible links between crustal composition, rifting history and present-day topography of the North Atlantic Region. Until present, seismic surveys have only been carried out offshore and near the coasts of Greenland, where the crustal structure is affected by oceanic break-up. We present the deep seismic structure of the crust of the interior of Greenland, based on the new and the only existing so far seismic refraction/wide-angle reflection profile. The seismic data was acquired by a team of six people during a two-month long experiment in summer of 2011 on the ice cap in the interior of central-eastern Greenland. The presence of an up to 3.4 km thick ice sheet, permanently covering most of the land mass, made acquisition of geophysical data logistically complicated. The profile extends 310 km inland in E-W direction from the approximate edge of the stable ice cap near the Scoresby Sund across the center of the ice cap. 350 Reftek Texan receivers recorded high-quality seismic data from 8 equidistant shots along the profile. Explosive charge sizes were 1 ton at the ends and ca. 500 kg along the profile, loaded with about 125 kg at 35-85 m depth in individual boreholes. Given that the data acquisition was affected by the thick ice sheet, we questioned the quality of seismic records in such experiment setup. We have developed an automatic routine to check the amplitudes and spectra of the selected seismic phases and to check the differences/challenges in making seismic experiments on ice and the effects of ice on data interpretation. Using tomographic inversion and forward ray tracing modelling we have obtained the two-dimensional velocity model down to a 50 km depth. The model shows a decrease of crustal thickness from 47 km below the centre of Greenland in the western part of the profile to 40 km in its eastern part. Relatively high lower crustal velocities (Vp 6.8 - 7.3 km/s) in the western part of the TopoGreenland profile may result from past collision tectonics or, alternatively, may be related to the speculated passage of the Iceland mantle plume. Comparison of our results with the new receiver function studies (Kraft et al., personal communication) suggests the possibility for a massive underplating along the profile. The origin of the pronounced circum-Atlantic mountain ranges in Norway and eastern Greenland, which have average elevation above 1500 m with peak elevations of more than 3.5 km near the Scoresby Sund in Eastern Greenland, is unknown. Our new results on the crustal structure provide constraints for assessment of the isostatic balance of the crust in Greenland, as well as for examining possible links between crustal composition, rifting history and present-day topography of the North Atlantic Region.
format Conference Object
author Shulgin, Alexey
Thybo, Hans
spellingShingle Shulgin, Alexey
Thybo, Hans
Crustal structure of the Central-Eastern Greenland: results from the Topo Greenland refraction profile
author_facet Shulgin, Alexey
Thybo, Hans
author_sort Shulgin, Alexey
title Crustal structure of the Central-Eastern Greenland: results from the Topo Greenland refraction profile
title_short Crustal structure of the Central-Eastern Greenland: results from the Topo Greenland refraction profile
title_full Crustal structure of the Central-Eastern Greenland: results from the Topo Greenland refraction profile
title_fullStr Crustal structure of the Central-Eastern Greenland: results from the Topo Greenland refraction profile
title_full_unstemmed Crustal structure of the Central-Eastern Greenland: results from the Topo Greenland refraction profile
title_sort crustal structure of the central-eastern greenland: results from the topo greenland refraction profile
publishDate 2014
url https://curis.ku.dk/portal/da/publications/crustal-structure-of-the-centraleastern-greenland-results-from-the-topo-greenland-refraction-profile(99e8ba97-bd7e-413e-ac49-a17b11f786a2).html
http://meetingorganizer.copernicus.org/EGU2014/EGU2014-9008.pdf
long_lat ENVELOPE(162.750,162.750,-66.567,-66.567)
ENVELOPE(-24.387,-24.387,70.476,70.476)
ENVELOPE(13.644,13.644,66.207,66.207)
geographic Greenland
Norway
Scoresby
Scoresby Sund
Sund
geographic_facet Greenland
Norway
Scoresby
Scoresby Sund
Sund
genre Greenland
Ice cap
Ice Sheet
Iceland
North Atlantic
Scoresby Sund
TopoGreenland
genre_facet Greenland
Ice cap
Ice Sheet
Iceland
North Atlantic
Scoresby Sund
TopoGreenland
op_source Shulgin , A & Thybo , H 2014 , ' Crustal structure of the Central-Eastern Greenland: results from the Topo Greenland refraction profile ' , Geophysical Research Abstracts , vol. 16 , 9008 . < http://meetingorganizer.copernicus.org/EGU2014/EGU2014-9008.pdf >
op_rights info:eu-repo/semantics/openAccess
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spelling ftcopenhagenunip:oai:pure.atira.dk:publications/99e8ba97-bd7e-413e-ac49-a17b11f786a2 2023-05-15T16:25:51+02:00 Crustal structure of the Central-Eastern Greenland: results from the Topo Greenland refraction profile Shulgin, Alexey Thybo, Hans 2014-04 https://curis.ku.dk/portal/da/publications/crustal-structure-of-the-centraleastern-greenland-results-from-the-topo-greenland-refraction-profile(99e8ba97-bd7e-413e-ac49-a17b11f786a2).html http://meetingorganizer.copernicus.org/EGU2014/EGU2014-9008.pdf eng eng info:eu-repo/semantics/openAccess Shulgin , A & Thybo , H 2014 , ' Crustal structure of the Central-Eastern Greenland: results from the Topo Greenland refraction profile ' , Geophysical Research Abstracts , vol. 16 , 9008 . < http://meetingorganizer.copernicus.org/EGU2014/EGU2014-9008.pdf > conferenceObject 2014 ftcopenhagenunip 2021-09-23T17:37:20Z Until present, seismic surveys have only been carried out offshore and near the coasts of Greenland, where the crustal structure is affected by oceanic break-up. We present the deep seismic structure of the crust of the interior of Greenland, based on the new and the only existing so far seismic refraction/wide-angle reflection profile. The seismic data was acquired by a team of six people during a two-month long experiment in summer of 2011 on the ice cap in the interior of central-eastern Greenland. The presence of an up to 3.4 km thick ice sheet, permanently covering most of the land mass, made acquisition of geophysical data logistically complicated. The profile extends 310 km inland in E-W direction from the approximate edge of the stable ice cap near the Scoresby Sund across the center of the ice cap. 350 Reftek Texan receivers recorded high-quality seismic data from 8 equidistant shots along the profile. Explosive charge sizes were 1 ton at the ends and ca. 500 kg along the profile, loaded with about 125 kg at 35-85 m depth in individual boreholes. Given that the data acquisition was affected by the thick ice sheet, we questioned the quality of seismic records in such experiment setup. We have developed an automatic routine to check the amplitudes and spectra of the selected seismic phases and to check the differences/challenges in making seismic experiments on ice and the effects of ice on data interpretation. Using tomographic inversion and forward ray tracing modelling we have obtained the two-dimensional velocity model down to a 50 km depth. The model shows a decrease of crustal thickness from 47 km below the centre of Greenland in the western part of the profile to 40 km in its eastern part. Relatively high lower crustal velocities (Vp 6.8 – 7.3 km/s) in the western part of the TopoGreenland profile may result from past collision tectonics or, alternatively, may be related to the speculated passage of the Iceland mantle plume. Comparison of our results with the new receiver function studies (Kraft et al., personal communication) suggests the possibility for a massive underplating along the profile. The origin of the pronounced circum-Atlantic mountain ranges in Norway and eastern Greenland, which have average elevation above 1500 m with peak elevations of more than 3.5 km near the Scoresby Sund in Eastern Greenland, is unknown. Our new results on the crustal structure provide constraints for assessment of the isostatic balance of the crust in Greenland, as well as for examining possible links between crustal composition, rifting history and present-day topography of the North Atlantic Region. Until present, seismic surveys have only been carried out offshore and near the coasts of Greenland, where the crustal structure is affected by oceanic break-up. We present the deep seismic structure of the crust of the interior of Greenland, based on the new and the only existing so far seismic refraction/wide-angle reflection profile. The seismic data was acquired by a team of six people during a two-month long experiment in summer of 2011 on the ice cap in the interior of central-eastern Greenland. The presence of an up to 3.4 km thick ice sheet, permanently covering most of the land mass, made acquisition of geophysical data logistically complicated. The profile extends 310 km inland in E-W direction from the approximate edge of the stable ice cap near the Scoresby Sund across the center of the ice cap. 350 Reftek Texan receivers recorded high-quality seismic data from 8 equidistant shots along the profile. Explosive charge sizes were 1 ton at the ends and ca. 500 kg along the profile, loaded with about 125 kg at 35-85 m depth in individual boreholes. Given that the data acquisition was affected by the thick ice sheet, we questioned the quality of seismic records in such experiment setup. We have developed an automatic routine to check the amplitudes and spectra of the selected seismic phases and to check the differences/challenges in making seismic experiments on ice and the effects of ice on data interpretation. Using tomographic inversion and forward ray tracing modelling we have obtained the two-dimensional velocity model down to a 50 km depth. The model shows a decrease of crustal thickness from 47 km below the centre of Greenland in the western part of the profile to 40 km in its eastern part. Relatively high lower crustal velocities (Vp 6.8 - 7.3 km/s) in the western part of the TopoGreenland profile may result from past collision tectonics or, alternatively, may be related to the speculated passage of the Iceland mantle plume. Comparison of our results with the new receiver function studies (Kraft et al., personal communication) suggests the possibility for a massive underplating along the profile. The origin of the pronounced circum-Atlantic mountain ranges in Norway and eastern Greenland, which have average elevation above 1500 m with peak elevations of more than 3.5 km near the Scoresby Sund in Eastern Greenland, is unknown. Our new results on the crustal structure provide constraints for assessment of the isostatic balance of the crust in Greenland, as well as for examining possible links between crustal composition, rifting history and present-day topography of the North Atlantic Region. Conference Object Greenland Ice cap Ice Sheet Iceland North Atlantic Scoresby Sund TopoGreenland University of Copenhagen: Research Greenland Norway Scoresby ENVELOPE(162.750,162.750,-66.567,-66.567) Scoresby Sund ENVELOPE(-24.387,-24.387,70.476,70.476) Sund ENVELOPE(13.644,13.644,66.207,66.207)

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