Tracing the sources of cave sulfates: a unique case from Cerna Valley, Romania
In order to reliably distinguish between different genetic processes of cave sulfate formation and to quantify the role of thermo-mineral waters on mineral deposition and cave morphology, it is critical to understand sulfur (S) sources and S transformations during hydrological and speleogenetic proc...
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ftusouthflorida:oai:digitalcommons.usf.edu:kip_articles-6331 2023-09-05T13:18:49+02:00 Tracing the sources of cave sulfates: a unique case from Cerna Valley, Romania Onac, Bogdan P. Wynn, Jonathan G. Sumrall, Jonathan B. 2011-09-25T07:00:00Z https://digitalcommons.usf.edu/kip_articles/5332 https://doi.org/10.1016/j.chemgeo.2011.07.006 unknown Digital Commons @ University of South Florida https://digitalcommons.usf.edu/kip_articles/5332 https://doi.org/10.1016/j.chemgeo.2011.07.006 KIP Articles Sulfur Isotopes Cave Sulfates Thermo-Mineral Springs Sulfuric Acid Speleogenesis text 2011 ftusouthflorida https://doi.org/10.1016/j.chemgeo.2011.07.006 2023-08-13T16:28:22Z In order to reliably distinguish between different genetic processes of cave sulfate formation and to quantify the role of thermo-mineral waters on mineral deposition and cave morphology, it is critical to understand sulfur (S) sources and S transformations during hydrological and speleogenetic processes. Previous work has shown that sulfuric acid speleogenesis (SAS) often produces sulfate deposits with 34S-depleted isotopic signatures compared to those of the original source of S in sulfate rocks. However, 34S-depleted isotopic composition of S-bearing minerals alone does not provide enough information to clearly distinguish SAS from other speleogenetic processes driven by carbonic acid, geothermal heat, or other processes. The isotopic composition (δ18O and δ34S) of sulfate minerals (mainly gypsum) from seven caves of the Cerna Valley (Romania) defines three distinct populations, and demonstrates that the δ34S values of SAS-precipitated cave sulfates depend not on the source of the S, but also on the H2S:SO42− ratio during aqueous S species reactions and mineral precipitation. Population 1 includes sulfates that are characterized by relatively low δ34S values (− 19.4 to − 27.9‰) with δ18O values between 0.2 and 4.3‰ that are consistent with oxidation of dissolved sulfide produced during methane-limited thermochemical sulfate reduction (TSR) that presently characterizes the chemistry of springs in the upper Cerna Valley. Population 2 of cave sulfates has 34S-enriched δ34S values (14.3 to 19.4‰) and more 18O-depleted δ18O values (from − 1.8 to − 10.0‰). These values argue for oxidation of dissolved sulfide produced during sulfate-limited TSR that presently characterizes the chemistry of springs further downstream in the Cerna Valley. The δ18O values of cave sulfates from Population 1 are consistent with oxidation under more oxic aqueous conditions than those of Population 2. δ34S values of cave sulfates within Population 3 (δ34S: 5.8 to 6.5‰) may be consistent with several scenarios (i.e., pyrite oxidation, oxid Text Carbonic acid University of South Florida St. Petersburg: Digital USFSP Chemical Geology 288 3-4 105 114 |
institution |
Open Polar |
collection |
University of South Florida St. Petersburg: Digital USFSP |
op_collection_id |
ftusouthflorida |
language |
unknown |
topic |
Sulfur Isotopes Cave Sulfates Thermo-Mineral Springs Sulfuric Acid Speleogenesis |
spellingShingle |
Sulfur Isotopes Cave Sulfates Thermo-Mineral Springs Sulfuric Acid Speleogenesis Onac, Bogdan P. Wynn, Jonathan G. Sumrall, Jonathan B. Tracing the sources of cave sulfates: a unique case from Cerna Valley, Romania |
topic_facet |
Sulfur Isotopes Cave Sulfates Thermo-Mineral Springs Sulfuric Acid Speleogenesis |
description |
In order to reliably distinguish between different genetic processes of cave sulfate formation and to quantify the role of thermo-mineral waters on mineral deposition and cave morphology, it is critical to understand sulfur (S) sources and S transformations during hydrological and speleogenetic processes. Previous work has shown that sulfuric acid speleogenesis (SAS) often produces sulfate deposits with 34S-depleted isotopic signatures compared to those of the original source of S in sulfate rocks. However, 34S-depleted isotopic composition of S-bearing minerals alone does not provide enough information to clearly distinguish SAS from other speleogenetic processes driven by carbonic acid, geothermal heat, or other processes. The isotopic composition (δ18O and δ34S) of sulfate minerals (mainly gypsum) from seven caves of the Cerna Valley (Romania) defines three distinct populations, and demonstrates that the δ34S values of SAS-precipitated cave sulfates depend not on the source of the S, but also on the H2S:SO42− ratio during aqueous S species reactions and mineral precipitation. Population 1 includes sulfates that are characterized by relatively low δ34S values (− 19.4 to − 27.9‰) with δ18O values between 0.2 and 4.3‰ that are consistent with oxidation of dissolved sulfide produced during methane-limited thermochemical sulfate reduction (TSR) that presently characterizes the chemistry of springs in the upper Cerna Valley. Population 2 of cave sulfates has 34S-enriched δ34S values (14.3 to 19.4‰) and more 18O-depleted δ18O values (from − 1.8 to − 10.0‰). These values argue for oxidation of dissolved sulfide produced during sulfate-limited TSR that presently characterizes the chemistry of springs further downstream in the Cerna Valley. The δ18O values of cave sulfates from Population 1 are consistent with oxidation under more oxic aqueous conditions than those of Population 2. δ34S values of cave sulfates within Population 3 (δ34S: 5.8 to 6.5‰) may be consistent with several scenarios (i.e., pyrite oxidation, oxid |
format |
Text |
author |
Onac, Bogdan P. Wynn, Jonathan G. Sumrall, Jonathan B. |
author_facet |
Onac, Bogdan P. Wynn, Jonathan G. Sumrall, Jonathan B. |
author_sort |
Onac, Bogdan P. |
title |
Tracing the sources of cave sulfates: a unique case from Cerna Valley, Romania |
title_short |
Tracing the sources of cave sulfates: a unique case from Cerna Valley, Romania |
title_full |
Tracing the sources of cave sulfates: a unique case from Cerna Valley, Romania |
title_fullStr |
Tracing the sources of cave sulfates: a unique case from Cerna Valley, Romania |
title_full_unstemmed |
Tracing the sources of cave sulfates: a unique case from Cerna Valley, Romania |
title_sort |
tracing the sources of cave sulfates: a unique case from cerna valley, romania |
publisher |
Digital Commons @ University of South Florida |
publishDate |
2011 |
url |
https://digitalcommons.usf.edu/kip_articles/5332 https://doi.org/10.1016/j.chemgeo.2011.07.006 |
genre |
Carbonic acid |
genre_facet |
Carbonic acid |
op_source |
KIP Articles |
op_relation |
https://digitalcommons.usf.edu/kip_articles/5332 https://doi.org/10.1016/j.chemgeo.2011.07.006 |
op_doi |
https://doi.org/10.1016/j.chemgeo.2011.07.006 |
container_title |
Chemical Geology |
container_volume |
288 |
container_issue |
3-4 |
container_start_page |
105 |
op_container_end_page |
114 |
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1776199678081105920 |