Base metal sulphide geochemistry of southern African mantle eclogites (Roberts Victor): Implications for cratonic mafic magmatism and metallogenesis
Base metal sulphide geochemistry of southern African mantle eclogites (Roberts Victor): Implications for cratonic mafic magmatism and metallogenesis
Platinum-group elements (PGE) display a chalcophile behaviour and are largely hosted by base metal sulphide (BMS) minerals in the mantle. During partial melting of the mantle, BMS release their metal budget into the magma generated. The fertility of magma sources is a key component of the mineralisation potential of large igneous provinces (LIP) and the origin of orthomagmatic sulphide deposits hosted in cratonic mafic magmatic systems. Fertility of mantle-derived magma is therefore predicated on our understanding of the abundance of metals, such as the PGE, in the asthenospheric and lithospheric mantle. Estimations of the abundance of chalcophile elements in the upper mantle are based on observations from mantle xenoliths and BMS inclusions in diamonds. Whilst previous assessments exist for the BMS composition and chalcophile element budget of peridotitic mantle, relatively few analyses have been published for eclogitic mantle. Here, we present sulphide petrography and an extensive in situ dataset of BMS trace element compositions from Roberts Victor eclogite xenoliths (Kaapvaal Craton, South Africa). The BMS are dominated by pyrite-chalcopyrite-pentlandite (± pyrrhotite) assemblages with S/Se ratios ranging 1200 to 36,840 (with 87% of analyses having S/Se this editing is incorrect. This should read “(with 87% of analyses having S/Se < 10,000)” Please note the <〈10,000). Total PGE abundance in BMS range from 0.17 to 223 ppm. We recognise four end-member compositions (types i to iv), distinguished by total PGE abundance and Pt/Pd and Au/Pd ratios. The majority of BMS have low PGE abundances (< 10 ppm) but Type iv BMS have the highest concentration of PGE recorded in eclogites so far (> 100 ppm) and are characteristically enriched in Os, Ir, Ru and Rh. Nano- and micron-scale Pd-Pt antimonide, telluride and arsenide platinum-group minerals (PGM) are observed spatially associated with BMS. We suggest that the predominance of pyrite in the xenoliths reflects the process of eclogitisation and that the trace element composition of the eclogite BMS was inherited from oceanic crustal protoliths of the eclogites, introduced into the SCLM via ancient subduction during formation of the Colesberg Magnetic Lineament c. 2.9 Ga and the cratonisation of the Kaapvaal Craton. Crucially, we demonstrate that the PGE budget of eclogitic SCLM may be substantially higher than previously reported, akin to peridotitic compositions, with significant implications for the PGE fertility of cratonic mafic magmatism and metallogenesis. We quantitatively assess these implications by modelling the chalcophile geochemistry of an eclogitic melt component in parental magmas of the mafic Rustenburg Layered Suite of the Bushveld Complex.
Base metal sulphide, Eclogite, Kaapvaal, Metallogenesis, PGE, Roberts Victor
Hughes, Hannah S.R.
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Compton-Jones, Charlie
921110d0-fea2-4673-8962-46adcbc99b34
Mcdonald, Iain
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Kiseeva, Ekaterina S.
ee969556-91a5-4374-9567-a215e83d72fb
Kamenetsky, Vadim S.
792b4373-1f05-4778-9eab-3bf7be14455c
Rollinson, Gavyn
64d30c89-3b26-44c4-b4c7-9857fa36aecd
Coggon, Judith A.
4af6bb17-68f7-4c65-bb9b-7212eca500fe
Kinnaird, Judith A.
7f8638ee-9579-407c-ac3e-e6495d9db358
Bybee, Grant M.
64c38202-9ffe-44d0-8abf-d047d502985e
1 February 2021
Hughes, Hannah S.R.
5674014c-7091-49f6-a007-37fd1b6f890b
Compton-Jones, Charlie
921110d0-fea2-4673-8962-46adcbc99b34
Mcdonald, Iain
22362420-baf6-46c4-8623-8db5be2ea46e
Kiseeva, Ekaterina S.
ee969556-91a5-4374-9567-a215e83d72fb
Kamenetsky, Vadim S.
792b4373-1f05-4778-9eab-3bf7be14455c
Rollinson, Gavyn
64d30c89-3b26-44c4-b4c7-9857fa36aecd
Coggon, Judith A.
4af6bb17-68f7-4c65-bb9b-7212eca500fe
Kinnaird, Judith A.
7f8638ee-9579-407c-ac3e-e6495d9db358
Bybee, Grant M.
64c38202-9ffe-44d0-8abf-d047d502985e
Hughes, Hannah S.R., Compton-Jones, Charlie, Mcdonald, Iain, Kiseeva, Ekaterina S., Kamenetsky, Vadim S., Rollinson, Gavyn, Coggon, Judith A., Kinnaird, Judith A. and Bybee, Grant M.
(2021)
Base metal sulphide geochemistry of southern African mantle eclogites (Roberts Victor): Implications for cratonic mafic magmatism and metallogenesis.
Lithos, 382-383, [105918].
(doi:10.1016/j.lithos.2020.105918).
Abstract
Platinum-group elements (PGE) display a chalcophile behaviour and are largely hosted by base metal sulphide (BMS) minerals in the mantle. During partial melting of the mantle, BMS release their metal budget into the magma generated. The fertility of magma sources is a key component of the mineralisation potential of large igneous provinces (LIP) and the origin of orthomagmatic sulphide deposits hosted in cratonic mafic magmatic systems. Fertility of mantle-derived magma is therefore predicated on our understanding of the abundance of metals, such as the PGE, in the asthenospheric and lithospheric mantle. Estimations of the abundance of chalcophile elements in the upper mantle are based on observations from mantle xenoliths and BMS inclusions in diamonds. Whilst previous assessments exist for the BMS composition and chalcophile element budget of peridotitic mantle, relatively few analyses have been published for eclogitic mantle. Here, we present sulphide petrography and an extensive in situ dataset of BMS trace element compositions from Roberts Victor eclogite xenoliths (Kaapvaal Craton, South Africa). The BMS are dominated by pyrite-chalcopyrite-pentlandite (± pyrrhotite) assemblages with S/Se ratios ranging 1200 to 36,840 (with 87% of analyses having S/Se this editing is incorrect. This should read “(with 87% of analyses having S/Se < 10,000)” Please note the <〈10,000). Total PGE abundance in BMS range from 0.17 to 223 ppm. We recognise four end-member compositions (types i to iv), distinguished by total PGE abundance and Pt/Pd and Au/Pd ratios. The majority of BMS have low PGE abundances (< 10 ppm) but Type iv BMS have the highest concentration of PGE recorded in eclogites so far (> 100 ppm) and are characteristically enriched in Os, Ir, Ru and Rh. Nano- and micron-scale Pd-Pt antimonide, telluride and arsenide platinum-group minerals (PGM) are observed spatially associated with BMS. We suggest that the predominance of pyrite in the xenoliths reflects the process of eclogitisation and that the trace element composition of the eclogite BMS was inherited from oceanic crustal protoliths of the eclogites, introduced into the SCLM via ancient subduction during formation of the Colesberg Magnetic Lineament c. 2.9 Ga and the cratonisation of the Kaapvaal Craton. Crucially, we demonstrate that the PGE budget of eclogitic SCLM may be substantially higher than previously reported, akin to peridotitic compositions, with significant implications for the PGE fertility of cratonic mafic magmatism and metallogenesis. We quantitatively assess these implications by modelling the chalcophile geochemistry of an eclogitic melt component in parental magmas of the mafic Rustenburg Layered Suite of the Bushveld Complex.
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Accepted/In Press date: 27 November 2020
e-pub ahead of print date: 9 December 2020
Published date: 1 February 2021
Additional Information:
Funding Information:
Steve Pendray and Joe Pickles are thanked for sample preparation and lab support, respectively. The research in Oxford University was financially supported by NERC grant NE/L010828/1 to ESK. VSK acknowledges funding by the Russian Science Foundation grant no. 16-17-10145 . IMcD acknowledges support from the Natural Environmental Research Council (NERC) under tellurium and selenium cycling and supply grant NE/M010848/1 . The authors thank Marek Locmellis, Marco Fiorentini and Steve Barnes for their constructive and thorough reviews, and José Maria Gonzalez-Jiménez for his editorial handling of the paper.
Funding Information:
Steve Pendray and Joe Pickles are thanked for sample preparation and lab support, respectively. The research in Oxford University was financially supported by NERC grant NE/L010828/1 to ESK. VSK acknowledges funding by the Russian Science Foundation grant no. 16-17-10145. IMcD acknowledges support from the Natural Environmental Research Council (NERC) under tellurium and selenium cycling and supply grant NE/M010848/1. The authors thank Marek Locmellis, Marco Fiorentini and Steve Barnes for their constructive and thorough reviews, and Jos? Maria Gonzalez-Jim?nez for his editorial handling of the paper.
Publisher Copyright:
© 2020
Keywords:
Base metal sulphide, Eclogite, Kaapvaal, Metallogenesis, PGE, Roberts Victor
Identifiers
Local EPrints ID: 449116
URI: http://eprints.soton.ac.uk/id/eprint/449116
ISSN: 0024-4937
PURE UUID: 466a1862-afb4-4c47-9d29-b3efb76946ab
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Date deposited: 17 May 2021 16:33
Last modified: 16 Mar 2024 10:41
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Contributors
Author:
Hannah S.R. Hughes
Author:
Charlie Compton-Jones
Author:
Iain Mcdonald
Author:
Ekaterina S. Kiseeva
Author:
Vadim S. Kamenetsky
Author:
Gavyn Rollinson
Author:
Judith A. Kinnaird
Author:
Grant M. Bybee
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