Continental carbonate facies of a Neoproterozoic panglaciation, north-east Svalbard

The Marinoan panglaciation (ca 650 to 635 Ma) is represented in north-east Svalbard by the 130 to 175 m thick Wilsonbreen Formation which contains syn-glacial carbonates in its upper 100 m. These sediments are now known to have been deposited under a CO 2 -rich atmosphere, late in the glaciation, an...

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Published in:Sedimentology
Main Authors: Fairchild, Ian J., Fleming, Edward J., Bao, Huiming, Benn, Douglas I., Boomer, Ian, Dublyansky, Yuri V., Halverson, Galen P., Hambrey, Michael J., Hendy, Chris, McMillan, Emily A., Spötl, Christoph, Stevenson, Carl T. E., Wynn, Peter M.
Format: Article in Journal/Newspaper
Language:English
Published: 2016
Subjects:
Carbon isotopes
Cryogenian
Ikaite pseudomorphs
Lacustrine
Oxygen isotopes
Snowball Earth
Svalbard
Online Access:https://risweb.st-andrews.ac.uk/portal/en/researchoutput/continental-carbonate-facies-of-a-neoproterozoic-panglaciation-northeast-svalbard(98dc5e8c-5383-4879-b856-9a061e588f10).html
https://doi.org/10.1111/sed.12252
https://research-repository.st-andrews.ac.uk/bitstream/10023/10231/1/Benn_2016_Sedimentology_Continental_AAM.pdf
id ftunstandrewcris:oai:risweb.st-andrews.ac.uk:publications/98dc5e8c-5383-4879-b856-9a061e588f10
record_format openpolar
spelling ftunstandrewcris:oai:risweb.st-andrews.ac.uk:publications/98dc5e8c-5383-4879-b856-9a061e588f10 2023-05-15T18:29:46+02:00 Continental carbonate facies of a Neoproterozoic panglaciation, north-east Svalbard Fairchild, Ian J. Fleming, Edward J. Bao, Huiming Benn, Douglas I. Boomer, Ian Dublyansky, Yuri V. Halverson, Galen P. Hambrey, Michael J. Hendy, Chris McMillan, Emily A. Spötl, Christoph Stevenson, Carl T. E. Wynn, Peter M. 2016-02 application/pdf https://risweb.st-andrews.ac.uk/portal/en/researchoutput/continental-carbonate-facies-of-a-neoproterozoic-panglaciation-northeast-svalbard(98dc5e8c-5383-4879-b856-9a061e588f10).html https://doi.org/10.1111/sed.12252 https://research-repository.st-andrews.ac.uk/bitstream/10023/10231/1/Benn_2016_Sedimentology_Continental_AAM.pdf eng eng info:eu-repo/semantics/openAccess Fairchild , I J , Fleming , E J , Bao , H , Benn , D I , Boomer , I , Dublyansky , Y V , Halverson , G P , Hambrey , M J , Hendy , C , McMillan , E A , Spötl , C , Stevenson , C T E & Wynn , P M 2016 , ' Continental carbonate facies of a Neoproterozoic panglaciation, north-east Svalbard ' , Sedimentology , vol. 63 , no. 2 , pp. 443-497 . https://doi.org/10.1111/sed.12252 Carbon isotopes Cryogenian Ikaite pseudomorphs Lacustrine Oxygen isotopes Snowball Earth article 2016 ftunstandrewcris https://doi.org/10.1111/sed.12252 2022-06-02T07:45:40Z The Marinoan panglaciation (ca 650 to 635 Ma) is represented in north-east Svalbard by the 130 to 175 m thick Wilsonbreen Formation which contains syn-glacial carbonates in its upper 100 m. These sediments are now known to have been deposited under a CO 2 -rich atmosphere, late in the glaciation, and global climate models facilitate testing of proposed analogues. Precipitated carbonates occur in four of the seven facies associations identified: Fluvial Channel (including stromatolitic and intraclastic limestones in ephemeral stream deposits); Dolomitic Floodplain (dolomite-cemented sand and siltstones, and microbial dolomites); Calcareous Lake Margin (intraclastic dolomite and wave-rippled or aeolian siliciclastic facies); and Calcareous Lake (slump-folded and locally re-sedimented rhythmic/stromatolitic limestones and dolomites associated with ice-rafted sediment). There is no strong cyclicity, and modern analogues suggest that sudden changes in lake level may exert a strong control on facies geometry. Both calcite and dolomite in stromatolites and rhythmites display either primary or early diagenetic replacive growth. Oxygen isotope values (−12 to +15‰ VPDB ) broadly covary with δ 13 C. High δ 13 C values of +3·5 to +4·5‰ correspond to equilibration with an atmosphere dominated by volcanically degassed CO 2 with δ 13 C of −6 to −7‰. Limestones have consistently negative δ 18 O values, while rhythmic and playa dolomites preserve intermediate compositions, and dolocretes possess slightly negative to strongly positive δ 18 O signatures, reflecting significant evaporation under hyperarid conditions. Inferred meltwater compositions (−8 to −15·5‰) could reflect smaller Rayleigh fractionation related to more limited cooling than in modern polar regions. A common pseudomorph morphology is interpreted as a replacement of ikaite (CaCO 3 ·H 2 O), which may also have been the precursor for widespread replacive calcite mosaics. Local dolomitization of lacustrine facies is interpreted to reflect microenvironments with ... Article in Journal/Newspaper Svalbard University of St Andrews: Research Portal Svalbard Sedimentology 63 2 443 497
institution Open Polar
collection University of St Andrews: Research Portal
op_collection_id ftunstandrewcris
language English
topic Carbon isotopes
Cryogenian
Ikaite pseudomorphs
Lacustrine
Oxygen isotopes
Snowball Earth
spellingShingle Carbon isotopes
Cryogenian
Ikaite pseudomorphs
Lacustrine
Oxygen isotopes
Snowball Earth
Fairchild, Ian J.
Fleming, Edward J.
Bao, Huiming
Benn, Douglas I.
Boomer, Ian
Dublyansky, Yuri V.
Halverson, Galen P.
Hambrey, Michael J.
Hendy, Chris
McMillan, Emily A.
Spötl, Christoph
Stevenson, Carl T. E.
Wynn, Peter M.
Continental carbonate facies of a Neoproterozoic panglaciation, north-east Svalbard
topic_facet Carbon isotopes
Cryogenian
Ikaite pseudomorphs
Lacustrine
Oxygen isotopes
Snowball Earth
description The Marinoan panglaciation (ca 650 to 635 Ma) is represented in north-east Svalbard by the 130 to 175 m thick Wilsonbreen Formation which contains syn-glacial carbonates in its upper 100 m. These sediments are now known to have been deposited under a CO 2 -rich atmosphere, late in the glaciation, and global climate models facilitate testing of proposed analogues. Precipitated carbonates occur in four of the seven facies associations identified: Fluvial Channel (including stromatolitic and intraclastic limestones in ephemeral stream deposits); Dolomitic Floodplain (dolomite-cemented sand and siltstones, and microbial dolomites); Calcareous Lake Margin (intraclastic dolomite and wave-rippled or aeolian siliciclastic facies); and Calcareous Lake (slump-folded and locally re-sedimented rhythmic/stromatolitic limestones and dolomites associated with ice-rafted sediment). There is no strong cyclicity, and modern analogues suggest that sudden changes in lake level may exert a strong control on facies geometry. Both calcite and dolomite in stromatolites and rhythmites display either primary or early diagenetic replacive growth. Oxygen isotope values (−12 to +15‰ VPDB ) broadly covary with δ 13 C. High δ 13 C values of +3·5 to +4·5‰ correspond to equilibration with an atmosphere dominated by volcanically degassed CO 2 with δ 13 C of −6 to −7‰. Limestones have consistently negative δ 18 O values, while rhythmic and playa dolomites preserve intermediate compositions, and dolocretes possess slightly negative to strongly positive δ 18 O signatures, reflecting significant evaporation under hyperarid conditions. Inferred meltwater compositions (−8 to −15·5‰) could reflect smaller Rayleigh fractionation related to more limited cooling than in modern polar regions. A common pseudomorph morphology is interpreted as a replacement of ikaite (CaCO 3 ·H 2 O), which may also have been the precursor for widespread replacive calcite mosaics. Local dolomitization of lacustrine facies is interpreted to reflect microenvironments with ...
format Article in Journal/Newspaper
author Fairchild, Ian J.
Fleming, Edward J.
Bao, Huiming
Benn, Douglas I.
Boomer, Ian
Dublyansky, Yuri V.
Halverson, Galen P.
Hambrey, Michael J.
Hendy, Chris
McMillan, Emily A.
Spötl, Christoph
Stevenson, Carl T. E.
Wynn, Peter M.
author_facet Fairchild, Ian J.
Fleming, Edward J.
Bao, Huiming
Benn, Douglas I.
Boomer, Ian
Dublyansky, Yuri V.
Halverson, Galen P.
Hambrey, Michael J.
Hendy, Chris
McMillan, Emily A.
Spötl, Christoph
Stevenson, Carl T. E.
Wynn, Peter M.
author_sort Fairchild, Ian J.
title Continental carbonate facies of a Neoproterozoic panglaciation, north-east Svalbard
title_short Continental carbonate facies of a Neoproterozoic panglaciation, north-east Svalbard
title_full Continental carbonate facies of a Neoproterozoic panglaciation, north-east Svalbard
title_fullStr Continental carbonate facies of a Neoproterozoic panglaciation, north-east Svalbard
title_full_unstemmed Continental carbonate facies of a Neoproterozoic panglaciation, north-east Svalbard
title_sort continental carbonate facies of a neoproterozoic panglaciation, north-east svalbard
publishDate 2016
url https://risweb.st-andrews.ac.uk/portal/en/researchoutput/continental-carbonate-facies-of-a-neoproterozoic-panglaciation-northeast-svalbard(98dc5e8c-5383-4879-b856-9a061e588f10).html
https://doi.org/10.1111/sed.12252
https://research-repository.st-andrews.ac.uk/bitstream/10023/10231/1/Benn_2016_Sedimentology_Continental_AAM.pdf
geographic Svalbard
geographic_facet Svalbard
genre Svalbard
genre_facet Svalbard
op_source Fairchild , I J , Fleming , E J , Bao , H , Benn , D I , Boomer , I , Dublyansky , Y V , Halverson , G P , Hambrey , M J , Hendy , C , McMillan , E A , Spötl , C , Stevenson , C T E & Wynn , P M 2016 , ' Continental carbonate facies of a Neoproterozoic panglaciation, north-east Svalbard ' , Sedimentology , vol. 63 , no. 2 , pp. 443-497 . https://doi.org/10.1111/sed.12252
op_rights info:eu-repo/semantics/openAccess
op_doi https://doi.org/10.1111/sed.12252
container_title Sedimentology
container_volume 63
container_issue 2
container_start_page 443
op_container_end_page 497
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