The tectonic evolution of the Arctic since Pangea breakup

This data collection is associated with the publication: Shephard, G. E., Müller, R. D., & Seton, M. (2013). The tectonic evolution of the Arctic since Pangea breakup: Integrating constraints from surface geology and geophysics with mantle structure. Earth-Science Reviews, 124(0), 148-183. doi:1...

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Bibliographic Details
Other Authors:	Dietmar Muller (hasAssociationWith), Maria Seton (hasCollector), Dietmar Muller (hasCollector)
Format:	Dataset
Language:	unknown
Published:	The University of Sydney
Subjects:	plate kinematics Cache Creek Ocean Slide Mountain Ocean South Anuyi Ocean Amerasia Basin Canada Basin Lomonosov Ridge Makarov Basin Podvodkikov Basin Oimyakon Ocean terrane accretion plate motion model subduction subduction polarity reversal seafloor spreading triple junction Jurassic Cretaceous Cenozoic mantle tomography geodynamics Stikinia terrane plate reconstruction Quesnellia terrane Gravina arc Talkeetna-Bonanza arc Laurentia Alpha-Mendeleev Ridge Laptev Sea plate tectonics Arctic Siberia North America Wrangellia Superterrane Yukon-Tanana Terrane Tectonics EARTH SCIENCES GEOLOGY GEOPHYSICS Marine Geoscience Expanding Knowledge in the Earth Sciences EXPANDING KNOWLEDGE Pure basic research Bonanza Canada Pacific Yukon canada basin laptev makarov basin
Online Access:	https://doi.org/10.4227/11/5587A8423127E https://doi.org/10.1016/j.earscirev.2013.05.012 https://researchdata.ands.org.au/tectonic-evolution-arctic-pangea-breakup/616573 http://www.earthbyte.org/Resources/Shephard_Arctic_Dataset.html

id	ftands:oai:ands.org.au::616573
record_format	openpolar
institution	Open Polar
collection	Research Data Australia (Australian National Data Service - ANDS)
op_collection_id	ftands
language	unknown
topic	plate kinematics Cache Creek Ocean Slide Mountain Ocean South Anuyi Ocean Amerasia Basin Canada Basin Lomonosov Ridge Makarov Basin Podvodkikov Basin Oimyakon Ocean terrane accretion plate motion model subduction subduction polarity reversal seafloor spreading triple junction Jurassic Cretaceous Cenozoic mantle tomography geodynamics Stikinia terrane plate reconstruction Quesnellia terrane Gravina arc Talkeetna-Bonanza arc Laurentia Alpha-Mendeleev Ridge Laptev Sea plate tectonics Arctic Siberia North America Wrangellia Superterrane Yukon-Tanana Terrane Tectonics EARTH SCIENCES GEOLOGY GEOPHYSICS Marine Geoscience Expanding Knowledge in the Earth Sciences EXPANDING KNOWLEDGE Pure basic research
spellingShingle	plate kinematics Cache Creek Ocean Slide Mountain Ocean South Anuyi Ocean Amerasia Basin Canada Basin Lomonosov Ridge Makarov Basin Podvodkikov Basin Oimyakon Ocean terrane accretion plate motion model subduction subduction polarity reversal seafloor spreading triple junction Jurassic Cretaceous Cenozoic mantle tomography geodynamics Stikinia terrane plate reconstruction Quesnellia terrane Gravina arc Talkeetna-Bonanza arc Laurentia Alpha-Mendeleev Ridge Laptev Sea plate tectonics Arctic Siberia North America Wrangellia Superterrane Yukon-Tanana Terrane Tectonics EARTH SCIENCES GEOLOGY GEOPHYSICS Marine Geoscience Expanding Knowledge in the Earth Sciences EXPANDING KNOWLEDGE Pure basic research The tectonic evolution of the Arctic since Pangea breakup
topic_facet	plate kinematics Cache Creek Ocean Slide Mountain Ocean South Anuyi Ocean Amerasia Basin Canada Basin Lomonosov Ridge Makarov Basin Podvodkikov Basin Oimyakon Ocean terrane accretion plate motion model subduction subduction polarity reversal seafloor spreading triple junction Jurassic Cretaceous Cenozoic mantle tomography geodynamics Stikinia terrane plate reconstruction Quesnellia terrane Gravina arc Talkeetna-Bonanza arc Laurentia Alpha-Mendeleev Ridge Laptev Sea plate tectonics Arctic Siberia North America Wrangellia Superterrane Yukon-Tanana Terrane Tectonics EARTH SCIENCES GEOLOGY GEOPHYSICS Marine Geoscience Expanding Knowledge in the Earth Sciences EXPANDING KNOWLEDGE Pure basic research
description	This data collection is associated with the publication: Shephard, G. E., Müller, R. D., & Seton, M. (2013). The tectonic evolution of the Arctic since Pangea breakup: Integrating constraints from surface geology and geophysics with mantle structure. Earth-Science Reviews, 124(0), 148-183. doi:10.1016/j.earscirev.2013.05.012 Publication Abstract The tectonic evolution of the circum-Arctic, including the northern Pacific, Siberian and North American margins, since the Jurassic has been punctuated by the opening and closing of ocean basins, the accretion of autochthonous and allochthonous terranes and associated deformation. This complexity is expressed in the uncertainty of plate tectonic models of the region, with the time-dependent configurations and kinematic history remaining poorly understood. The age, location, geometry and convergence rates of the subduction zones associated with these ancient ocean basins have implications for mantle structure, which can be used as an additional constraint for refining and evaluating plate boundary models. Here we integrate surface geology and geophysics with mantle tomography models to generate a digital set of tectonic blocks and plates as well as topologically closed plate boundaries with time-dependent rotational histories for the circum-Arctic. We find that subducted slabs inferred from seismic velocity anomalies from global P and S wave tomography models can be linked to various episodes of Arctic subduction since the Jurassic, in particular to the destruction of the South Anuyi Ocean. We present a refined model for the opening of the Amerasia Basin incorporating seafloor spreading between at least 142.5 and 120 Ma, a “windshield” rotation for the Canada Basin, and opening orthogonal to the Lomonosov Ridge for the northern Makarov and Podvodnikov basins. We also present a refined pre-accretionary model for the Wrangellia Superterrane, imposing a subduction polarity reversal in the early Jurassic before accretion to North America at 140 Ma. Our model accounts for the late Palaeozoic to early Mesozoic opening and closure of the Cache Creek Ocean, reconstructed between the Wrangellia Superterrane and Yukon–Tanana Terrane. We suggest that a triple junction may also explain the Mid-Palaeozoic opening of the Slide Mountain, Oimyakon and South Anuyi oceans. Our digital tectonic model forms the basis for the development of future plate deformation and geodynamic models and provides a framework for analysing the formation and evolution of regional sedimentary basins and mountain belts. Authors and Institutions Grace E. Shephard - EarthByte Research Group, School of Geosciences, The University of Sydney, Australia. ORCID: 0000-0002-3459-4500 Maria Seton - EarthByte Research Group, School of Geosciences, The University of Sydney, Australia. ORCID: 0000-0001-8541-1367 R. Dietmar Müller - EarthByte Research Group, School of Geosciences, The University of Sydney, Australia. ORCID: 0000-0002-3334-5764 Overview of Resources Contained This data collection includes the all of the files needed to visualise, recreate, and interact with the plate motion model developed and published in Shephard et al. (2013). The WGS 1984 datum is used for all shapefiles List of Resources Note: For details on the files included in this data collection, see “Description_of_Resources.txt”. Note: For information on file formats and what programs to use to interact with various file formats, see “File_Formats_and_Recommended_Programs.txt”. Rotation file for the tectonic model (.rot, 373 KB) Present day coastlines (.gpml, .kml, .txt, .shp, total 46.8 MB) Age coded static polygons for the continents and oceans (.gpml, .kml, .txt, .shp, total 28.8 MB) Time-dependent plate boundaries (.gpml, .shp, .txt, total 60.8 MB) For more information on this data collection, and links to other datasets from the EarthByte Research Group please visit EarthByte For more information about using GPlates, including tutorials and a user manual please visit GPlates or EarthByte
author2	Dietmar Muller (hasAssociationWith) Maria Seton (hasCollector) Dietmar Muller (hasCollector)
format	Dataset
title	The tectonic evolution of the Arctic since Pangea breakup
title_short	The tectonic evolution of the Arctic since Pangea breakup
title_full	The tectonic evolution of the Arctic since Pangea breakup
title_fullStr	The tectonic evolution of the Arctic since Pangea breakup
title_full_unstemmed	The tectonic evolution of the Arctic since Pangea breakup
title_sort	tectonic evolution of the arctic since pangea breakup
publisher	The University of Sydney
url	https://doi.org/10.4227/11/5587A8423127E https://doi.org/10.1016/j.earscirev.2013.05.012 https://researchdata.ands.org.au/tectonic-evolution-arctic-pangea-breakup/616573 http://www.earthbyte.org/Resources/Shephard_Arctic_Dataset.html
op_coverage	Spatial: Global
long_lat	ENVELOPE(-170.000,-170.000,80.000,80.000) ENVELOPE(-119.820,-119.820,55.917,55.917) ENVELOPE(170.000,170.000,87.000,87.000)
geographic	Amerasia Basin Arctic Bonanza Canada Laptev Sea Makarov Basin Pacific Yukon
geographic_facet	Amerasia Basin Arctic Bonanza Canada Laptev Sea Makarov Basin Pacific Yukon
genre	Arctic Arctic canada basin laptev Laptev Sea Lomonosov Ridge makarov basin Siberia Yukon
genre_facet	Arctic Arctic canada basin laptev Laptev Sea Lomonosov Ridge makarov basin Siberia Yukon
op_source	https://rdmp.sydney.edu.au/redbox/default
op_relation	https://researchdata.ands.org.au/tectonic-evolution-arctic-pangea-breakup/616573 http://dx.doi.org/10.4227/11/5587A8423127E http://doi.org/10.1016/j.earscirev.2013.05.012 http://www.earthbyte.org/Resources/Shephard_Arctic_Dataset.html
op_doi	https://doi.org/10.4227/11/5587A8423127E https://doi.org/10.1016/j.earscirev.2013.05.012
_version_	1766295490871164928
spelling	ftands:oai:ands.org.au::616573 2023-05-15T14:23:00+02:00 The tectonic evolution of the Arctic since Pangea breakup Dietmar Muller (hasAssociationWith) Maria Seton (hasCollector) Dietmar Muller (hasCollector) Spatial: Global https://doi.org/10.4227/11/5587A8423127E https://doi.org/10.1016/j.earscirev.2013.05.012 https://researchdata.ands.org.au/tectonic-evolution-arctic-pangea-breakup/616573 http://www.earthbyte.org/Resources/Shephard_Arctic_Dataset.html unknown The University of Sydney https://researchdata.ands.org.au/tectonic-evolution-arctic-pangea-breakup/616573 http://dx.doi.org/10.4227/11/5587A8423127E http://doi.org/10.1016/j.earscirev.2013.05.012 http://www.earthbyte.org/Resources/Shephard_Arctic_Dataset.html https://rdmp.sydney.edu.au/redbox/default plate kinematics Cache Creek Ocean Slide Mountain Ocean South Anuyi Ocean Amerasia Basin Canada Basin Lomonosov Ridge Makarov Basin Podvodkikov Basin Oimyakon Ocean terrane accretion plate motion model subduction subduction polarity reversal seafloor spreading triple junction Jurassic Cretaceous Cenozoic mantle tomography geodynamics Stikinia terrane plate reconstruction Quesnellia terrane Gravina arc Talkeetna-Bonanza arc Laurentia Alpha-Mendeleev Ridge Laptev Sea plate tectonics Arctic Siberia North America Wrangellia Superterrane Yukon-Tanana Terrane Tectonics EARTH SCIENCES GEOLOGY GEOPHYSICS Marine Geoscience Expanding Knowledge in the Earth Sciences EXPANDING KNOWLEDGE Pure basic research dataset ftands https://doi.org/10.4227/11/5587A8423127E https://doi.org/10.1016/j.earscirev.2013.05.012 2020-01-05T20:41:51Z This data collection is associated with the publication: Shephard, G. E., Müller, R. D., & Seton, M. (2013). The tectonic evolution of the Arctic since Pangea breakup: Integrating constraints from surface geology and geophysics with mantle structure. Earth-Science Reviews, 124(0), 148-183. doi:10.1016/j.earscirev.2013.05.012 Publication Abstract The tectonic evolution of the circum-Arctic, including the northern Pacific, Siberian and North American margins, since the Jurassic has been punctuated by the opening and closing of ocean basins, the accretion of autochthonous and allochthonous terranes and associated deformation. This complexity is expressed in the uncertainty of plate tectonic models of the region, with the time-dependent configurations and kinematic history remaining poorly understood. The age, location, geometry and convergence rates of the subduction zones associated with these ancient ocean basins have implications for mantle structure, which can be used as an additional constraint for refining and evaluating plate boundary models. Here we integrate surface geology and geophysics with mantle tomography models to generate a digital set of tectonic blocks and plates as well as topologically closed plate boundaries with time-dependent rotational histories for the circum-Arctic. We find that subducted slabs inferred from seismic velocity anomalies from global P and S wave tomography models can be linked to various episodes of Arctic subduction since the Jurassic, in particular to the destruction of the South Anuyi Ocean. We present a refined model for the opening of the Amerasia Basin incorporating seafloor spreading between at least 142.5 and 120 Ma, a “windshield” rotation for the Canada Basin, and opening orthogonal to the Lomonosov Ridge for the northern Makarov and Podvodnikov basins. We also present a refined pre-accretionary model for the Wrangellia Superterrane, imposing a subduction polarity reversal in the early Jurassic before accretion to North America at 140 Ma. Our model accounts for the late Palaeozoic to early Mesozoic opening and closure of the Cache Creek Ocean, reconstructed between the Wrangellia Superterrane and Yukon–Tanana Terrane. We suggest that a triple junction may also explain the Mid-Palaeozoic opening of the Slide Mountain, Oimyakon and South Anuyi oceans. Our digital tectonic model forms the basis for the development of future plate deformation and geodynamic models and provides a framework for analysing the formation and evolution of regional sedimentary basins and mountain belts. Authors and Institutions Grace E. Shephard - EarthByte Research Group, School of Geosciences, The University of Sydney, Australia. ORCID: 0000-0002-3459-4500 Maria Seton - EarthByte Research Group, School of Geosciences, The University of Sydney, Australia. ORCID: 0000-0001-8541-1367 R. Dietmar Müller - EarthByte Research Group, School of Geosciences, The University of Sydney, Australia. ORCID: 0000-0002-3334-5764 Overview of Resources Contained This data collection includes the all of the files needed to visualise, recreate, and interact with the plate motion model developed and published in Shephard et al. (2013). The WGS 1984 datum is used for all shapefiles List of Resources Note: For details on the files included in this data collection, see “Description_of_Resources.txt”. Note: For information on file formats and what programs to use to interact with various file formats, see “File_Formats_and_Recommended_Programs.txt”. Rotation file for the tectonic model (.rot, 373 KB) Present day coastlines (.gpml, .kml, .txt, .shp, total 46.8 MB) Age coded static polygons for the continents and oceans (.gpml, .kml, .txt, .shp, total 28.8 MB) Time-dependent plate boundaries (.gpml, .shp, .txt, total 60.8 MB) For more information on this data collection, and links to other datasets from the EarthByte Research Group please visit EarthByte For more information about using GPlates, including tutorials and a user manual please visit GPlates or EarthByte Dataset Arctic Arctic canada basin laptev Laptev Sea Lomonosov Ridge makarov basin Siberia Yukon Research Data Australia (Australian National Data Service - ANDS) Amerasia Basin ENVELOPE(-170.000,-170.000,80.000,80.000) Arctic Bonanza ENVELOPE(-119.820,-119.820,55.917,55.917) Canada Laptev Sea Makarov Basin ENVELOPE(170.000,170.000,87.000,87.000) Pacific Yukon

The tectonic evolution of the Arctic since Pangea breakup

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