An active mantle mechanism for Gondwana breakup

Despite over thirty years of plate tectonic theory, the reasons why supercontinents like Gondwana disintegrate into smaller continents and disperse remain enigmatic. Current ideas mostly involve changes in plate-boundary driving forces (passive mantle hypothesis) in preference to an active plume mec...

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Main Authors: Storey, B.C., Kyle, P.R.
Format: Article in Journal/Newspaper
Language:unknown
Published: 1997
Subjects:
Pacific
Patagonia
Antarc*
Antarctica
Online Access:http://nora.nerc.ac.uk/id/eprint/514720/
id ftnerc:oai:nora.nerc.ac.uk:514720
record_format openpolar
spelling ftnerc:oai:nora.nerc.ac.uk:514720 2023-12-24T10:09:37+01:00 An active mantle mechanism for Gondwana breakup Storey, B.C. Kyle, P.R. 1997 http://nora.nerc.ac.uk/id/eprint/514720/ unknown Storey, B.C.; Kyle, P.R. 1997 An active mantle mechanism for Gondwana breakup. South African Journal of Geology, 100 (4). 283-290. Publication - Article PeerReviewed 1997 ftnerc 2023-11-24T00:03:08Z Despite over thirty years of plate tectonic theory, the reasons why supercontinents like Gondwana disintegrate into smaller continents and disperse remain enigmatic. Current ideas mostly involve changes in plate-boundary driving forces (passive mantle hypothesis) in preference to an active plume mechanism, even though mantle plumes were present at most stages of Gondwana breakup. The role of these plumes in the breakup process is uncertain, and ideas vary from the chance unroofing of a pre-existing plume, which only contributed in the production of extensive flood basalts, to plumes that controlled the position of breakup. The magmatic and tectonic record along the proto-Pacific margin of Gondwana indicates that there were important changes in subduction zone forces during the initial stages of Gondwana breakup. However, the absence of subduction along the Neotethyan margin at the time of breakup, together with the fact that the initial rift formed almost at right angles to the active subducting margin, suggest a potential active role for a mantle plume in the initial separation. An active mantle mechanism, involving a very large thermal disturbance or megaplume, may, in contrast to a passive mantle hypothesis, more readily explain the formation and rotation of microplates in the South Atlantic region. It accounts also for the production of unusually large igneous provinces (Chon Aike province in Patagonia, Karoo province in southern Africa, and Ferrar province in Antarctica) just prior to breakup. Article in Journal/Newspaper Antarc* Antarctica Natural Environment Research Council: NERC Open Research Archive Pacific Patagonia
institution Open Polar
collection Natural Environment Research Council: NERC Open Research Archive
op_collection_id ftnerc
language unknown
description Despite over thirty years of plate tectonic theory, the reasons why supercontinents like Gondwana disintegrate into smaller continents and disperse remain enigmatic. Current ideas mostly involve changes in plate-boundary driving forces (passive mantle hypothesis) in preference to an active plume mechanism, even though mantle plumes were present at most stages of Gondwana breakup. The role of these plumes in the breakup process is uncertain, and ideas vary from the chance unroofing of a pre-existing plume, which only contributed in the production of extensive flood basalts, to plumes that controlled the position of breakup. The magmatic and tectonic record along the proto-Pacific margin of Gondwana indicates that there were important changes in subduction zone forces during the initial stages of Gondwana breakup. However, the absence of subduction along the Neotethyan margin at the time of breakup, together with the fact that the initial rift formed almost at right angles to the active subducting margin, suggest a potential active role for a mantle plume in the initial separation. An active mantle mechanism, involving a very large thermal disturbance or megaplume, may, in contrast to a passive mantle hypothesis, more readily explain the formation and rotation of microplates in the South Atlantic region. It accounts also for the production of unusually large igneous provinces (Chon Aike province in Patagonia, Karoo province in southern Africa, and Ferrar province in Antarctica) just prior to breakup.
format Article in Journal/Newspaper
author Storey, B.C.
Kyle, P.R.
spellingShingle Storey, B.C.
Kyle, P.R.
An active mantle mechanism for Gondwana breakup
author_facet Storey, B.C.
Kyle, P.R.
author_sort Storey, B.C.
title An active mantle mechanism for Gondwana breakup
title_short An active mantle mechanism for Gondwana breakup
title_full An active mantle mechanism for Gondwana breakup
title_fullStr An active mantle mechanism for Gondwana breakup
title_full_unstemmed An active mantle mechanism for Gondwana breakup
title_sort active mantle mechanism for gondwana breakup
publishDate 1997
url http://nora.nerc.ac.uk/id/eprint/514720/
geographic Pacific
Patagonia
geographic_facet Pacific
Patagonia
genre Antarc*
Antarctica
genre_facet Antarc*
Antarctica
op_relation Storey, B.C.; Kyle, P.R. 1997 An active mantle mechanism for Gondwana breakup. South African Journal of Geology, 100 (4). 283-290.
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