Sulfur (34S/32S) isotope composition of gypsum and implications for deep cave formation on the Nullarbor Plain, Australia

Sulfur (34S/32S) isotope composition of gypsum and implications for deep cave formation on the Nullarbor Plain, Australia

Large deep caves with little relation to surface topography are distinctive karst features on the Nullarbor Plain of Australia. The presence of gypsum deposits and chemoautotrophic bacteria within the caves have been suggested as evidence for cave formation and (or) enlargement via sulfuric acid spe...

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Bibliographic Details
Main Authors: Matej Lipar, Mateja Ferk, Sonja Lojen, Milo Barham
Format: Article
Language:English
Published: University of South Florida Libraries 2019-01-01
Series:International Journal of Speleology
Subjects:
gypsum
sulfuric acid speleogenesis
karst
cave
Australia
Online Access:https://scholarcommons.usf.edu/ijs/vol48/iss1/1/
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spelling doaj-2278899de05c41c79bc1d68009b952ac2021-05-02T06:44:45ZengUniversity of South Florida LibrariesInternational Journal of Speleology0392-66721827-806X2019-01-014811910.5038/1827-806X.48.1.2196Sulfur (34S/32S) isotope composition of gypsum and implications for deep cave formation on the Nullarbor Plain, AustraliaMatej Lipar0Mateja Ferk1Sonja Lojen2Milo Barham3Anton Melik Geographical InstituteAnton Melik Geographical InstituteJožef Stefan Institute & University of Nova GoricaCurtin UniversityLarge deep caves with little relation to surface topography are distinctive karst features on the Nullarbor Plain of Australia. The presence of gypsum deposits and chemoautotrophic bacteria within the caves have been suggested as evidence for cave formation and (or) enlargement via sulfuric acid speleogenesis. To test this hypothesis, the stable sulfur isotope compositions (δ34S) of both cave gypsum and surface gypsum were measured. Analyses yielded relatively high, positive δ34S values from both cave gypsum and surface gypsum, arguing against gypsum genesis via microbial chemoautotrophy, and more broadly, sulfuric acid speleogenesis. Instead, the gypsum is interpreted as forming via evaporation of seawater during the Quaternary.https://scholarcommons.usf.edu/ijs/vol48/iss1/1/gypsumsulfuric acid speleogenesiskarstcaveAustralia
collection DOAJ
language English
format Article
sources DOAJ
author Matej Lipar
Mateja Ferk
Sonja Lojen
Milo Barham
spellingShingle Matej Lipar
Mateja Ferk
Sonja Lojen
Milo Barham
Sulfur (34S/32S) isotope composition of gypsum and implications for deep cave formation on the Nullarbor Plain, Australia
International Journal of Speleology
gypsum
sulfuric acid speleogenesis
karst
cave
Australia
author_facet Matej Lipar
Mateja Ferk
Sonja Lojen
Milo Barham
author_sort Matej Lipar
title Sulfur (34S/32S) isotope composition of gypsum and implications for deep cave formation on the Nullarbor Plain, Australia
title_short Sulfur (34S/32S) isotope composition of gypsum and implications for deep cave formation on the Nullarbor Plain, Australia
title_full Sulfur (34S/32S) isotope composition of gypsum and implications for deep cave formation on the Nullarbor Plain, Australia
title_fullStr Sulfur (34S/32S) isotope composition of gypsum and implications for deep cave formation on the Nullarbor Plain, Australia
title_full_unstemmed Sulfur (34S/32S) isotope composition of gypsum and implications for deep cave formation on the Nullarbor Plain, Australia
title_sort sulfur (34s/32s) isotope composition of gypsum and implications for deep cave formation on the nullarbor plain, australia
publisher University of South Florida Libraries
series International Journal of Speleology
issn 0392-6672
1827-806X
publishDate 2019-01-01
description Large deep caves with little relation to surface topography are distinctive karst features on the Nullarbor Plain of Australia. The presence of gypsum deposits and chemoautotrophic bacteria within the caves have been suggested as evidence for cave formation and (or) enlargement via sulfuric acid speleogenesis. To test this hypothesis, the stable sulfur isotope compositions (δ34S) of both cave gypsum and surface gypsum were measured. Analyses yielded relatively high, positive δ34S values from both cave gypsum and surface gypsum, arguing against gypsum genesis via microbial chemoautotrophy, and more broadly, sulfuric acid speleogenesis. Instead, the gypsum is interpreted as forming via evaporation of seawater during the Quaternary.
topic gypsum
sulfuric acid speleogenesis
karst
cave
Australia
url https://scholarcommons.usf.edu/ijs/vol48/iss1/1/
work_keys_str_mv AT matejlipar sulfur34s32sisotopecompositionofgypsumandimplicationsfordeepcaveformationonthenullarborplainaustralia
AT matejaferk sulfur34s32sisotopecompositionofgypsumandimplicationsfordeepcaveformationonthenullarborplainaustralia
AT sonjalojen sulfur34s32sisotopecompositionofgypsumandimplicationsfordeepcaveformationonthenullarborplainaustralia
AT milobarham sulfur34s32sisotopecompositionofgypsumandimplicationsfordeepcaveformationonthenullarborplainaustralia
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