Dyke Architecture, Mineral Layering, and Magmatic Convection; New Perspectives from the Younger Giant Dyke Complex, S Greenland

Igneous sheet intrusions are a fundamental component of volcano plumbing systems. Identifying how sheet intrusion emplacement and geometry controls later magmatic processes is critical to understanding the distribution of volcanic eruptions and magma-related ore deposits. Using the Younger Giant Dyk...

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Main Authors: Koopmans, L, McCarthy, W, Magee, C
Format: Article in Journal/Newspaper
Language:unknown
Published: Wiley 2022
Subjects:
Greenland
Online Access:https://eprints.whiterose.ac.uk/183679/
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spelling ftleedsuniv:oai:eprints.whiterose.ac.uk:183679 2023-05-15T16:27:53+02:00 Dyke Architecture, Mineral Layering, and Magmatic Convection; New Perspectives from the Younger Giant Dyke Complex, S Greenland Koopmans, L McCarthy, W Magee, C 2022-02-22 https://eprints.whiterose.ac.uk/183679/ unknown Wiley Koopmans, L, McCarthy, W and Magee, C orcid.org/0000-0001-9836-2365 (2022) Dyke Architecture, Mineral Layering, and Magmatic Convection; New Perspectives from the Younger Giant Dyke Complex, S Greenland. Geochemistry, Geophysics, Geosystems. e2021GC010260. ISSN 1525-2027 Article NonPeerReviewed 2022 ftleedsuniv 2023-01-30T22:44:42Z Igneous sheet intrusions are a fundamental component of volcano plumbing systems. Identifying how sheet intrusion emplacement and geometry controls later magmatic processes is critical to understanding the distribution of volcanic eruptions and magma-related ore deposits. Using the Younger Giant Dyke Complex, a Mesoproterozoic suite of large (< 800 m wide) mafic dykes in southern Greenland, we assess the influence sheet of emplacement and geometry on subsequent magma flow and mush evolution. Through structural mapping, petrographic observations, and anisotropy of magnetic susceptibility fabric analyses, we show that the Younger Giant Dyke Complex was emplaced as a series of individual dyke segments, which following coalescence into a sheet intrusion remained largely isolated during their magmatic evolution. Through petrographic evidence for liquid-rich growth of cumulus phases, concentric magnetic fabrics, and the detailed study layered zones within the Younger Giant Dyke Complex, we infer magma convection occurred within the cores of each dyke element. We particularly relate layering to hydrodynamic sorting processes at a magma-mush boundary towards the base of each convection cell. Overall, our work demonstrates that the initial geometry of sheet intrusions can constrain magma flow patterns and affect the distribution of crystallisation regimes. Article in Journal/Newspaper Greenland White Rose Research Online (Universities of Leeds, Sheffield & York) Greenland
institution Open Polar
collection White Rose Research Online (Universities of Leeds, Sheffield & York)
op_collection_id ftleedsuniv
language unknown
description Igneous sheet intrusions are a fundamental component of volcano plumbing systems. Identifying how sheet intrusion emplacement and geometry controls later magmatic processes is critical to understanding the distribution of volcanic eruptions and magma-related ore deposits. Using the Younger Giant Dyke Complex, a Mesoproterozoic suite of large (< 800 m wide) mafic dykes in southern Greenland, we assess the influence sheet of emplacement and geometry on subsequent magma flow and mush evolution. Through structural mapping, petrographic observations, and anisotropy of magnetic susceptibility fabric analyses, we show that the Younger Giant Dyke Complex was emplaced as a series of individual dyke segments, which following coalescence into a sheet intrusion remained largely isolated during their magmatic evolution. Through petrographic evidence for liquid-rich growth of cumulus phases, concentric magnetic fabrics, and the detailed study layered zones within the Younger Giant Dyke Complex, we infer magma convection occurred within the cores of each dyke element. We particularly relate layering to hydrodynamic sorting processes at a magma-mush boundary towards the base of each convection cell. Overall, our work demonstrates that the initial geometry of sheet intrusions can constrain magma flow patterns and affect the distribution of crystallisation regimes.
format Article in Journal/Newspaper
author Koopmans, L
McCarthy, W
Magee, C
spellingShingle Koopmans, L
McCarthy, W
Magee, C
Dyke Architecture, Mineral Layering, and Magmatic Convection; New Perspectives from the Younger Giant Dyke Complex, S Greenland
author_facet Koopmans, L
McCarthy, W
Magee, C
author_sort Koopmans, L
title Dyke Architecture, Mineral Layering, and Magmatic Convection; New Perspectives from the Younger Giant Dyke Complex, S Greenland
title_short Dyke Architecture, Mineral Layering, and Magmatic Convection; New Perspectives from the Younger Giant Dyke Complex, S Greenland
title_full Dyke Architecture, Mineral Layering, and Magmatic Convection; New Perspectives from the Younger Giant Dyke Complex, S Greenland
title_fullStr Dyke Architecture, Mineral Layering, and Magmatic Convection; New Perspectives from the Younger Giant Dyke Complex, S Greenland
title_full_unstemmed Dyke Architecture, Mineral Layering, and Magmatic Convection; New Perspectives from the Younger Giant Dyke Complex, S Greenland
title_sort dyke architecture, mineral layering, and magmatic convection; new perspectives from the younger giant dyke complex, s greenland
publisher Wiley
publishDate 2022
url https://eprints.whiterose.ac.uk/183679/
geographic Greenland
geographic_facet Greenland
genre Greenland
genre_facet Greenland
op_relation Koopmans, L, McCarthy, W and Magee, C orcid.org/0000-0001-9836-2365 (2022) Dyke Architecture, Mineral Layering, and Magmatic Convection; New Perspectives from the Younger Giant Dyke Complex, S Greenland. Geochemistry, Geophysics, Geosystems. e2021GC010260. ISSN 1525-2027
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