Details
| Original language | English |
|---|---|
| Pages (from-to) | 27-46 |
| Number of pages | 20 |
| Journal | Chemical geology |
| Volume | 312-313 |
| Publication status | Published - 18 Jun 2012 |
Abstract
The mineralogy, sulfur contents, and multiple sulfur isotopic compositions were determined for a complete section through the Oman ophiolite at the Wadi Gideah area located in the Wadi Tayin Massif (southern domain of the ophiolite complex) in order to characterize the various processes of sulfur cycling in the Oman ophiolite which is regarded as representing the best example of fast-spreading oceanic lithosphere on land. Upper crustal rocks (lavas and sheeted dikes) exhibit pervasive alteration due to intense circulation of seawater. Sulfate is the dominant sulfur phase, and sulfur (δ 34S) and oxygen isotopic compositions of sulfate suggest that sulfate is mainly derived from late Cretaceous seawater. 34S enrichments in sulfides (with respect to mantle sulfur) and low sulfide-S contents (<10ppm) reflect precipitation of hydrothermal sulfides followed by oxidation of sulfides during seafloor weathering. Clearly negative δ 34S values of CRS (Cr-reducible sulfur) in one pillow basalt sample indicate that microbial reduction of seawater sulfate occurred within the lavas during low-temperature alteration. Rocks of the gabbro/sheeted dike transition zone display variable δ 34S CRS values (between 0.5‰ and 5.5‰) paired with a wide range in sulfide-S contents (<1 to 489ppm). This reflects the dynamic nature of this interface between the hydrothermal circulation system of the upper crust and the magmatic system dominating the lower crust. Low δ 34S sulfate-S values indicate that sulfate in those rocks mainly results from oxidation of igneous sulfides. Although lower crustal rocks of the Oman ophiolite are affected by high-temperature alteration resulting in leaching and redistribution of sulfide-S, δ 34S values of monosulfide and disulfide minerals scatter around the value for mantle sulfur (0‰). δ 33S* values of CRS between -0.020‰ and -0.038‰ clearly differ from those of upper crustal rocks. Either this documents leaching processes operating in the lower crust, or lower crustal rocks have preserved a primary multiple sulfur isotopic composition that deviates from the postulated mantle value (δ 33S*=0.0‰).Rocks from the mantle sequence of the Oman ophiolite are affected by serpentinization under highly reducing conditions at low water-rock ratios followed by a further stage of serpentinization under oxidizing conditions at high water-rock ratios. The first stage of alteration results in loss of sulfur (sulfide-S contents <60ppm) paired with δ 34S sulfide values around 0‰. The second stage leads to 34S-enriched sulfide phases and also low sulfide-S contents. Sulfate-S contents vary from 5ppm to 213ppm and are generally higher than in the lower crust. Sulfur and oxygen isotopic compositions of sulfate suggest that sulfate is mainly derived from late Cretaceous seawater.
Keywords
- Fast-spreading oceanic crust, Multiple sulfur isotopes, Oman ophiolite, Sulfur cycling
ASJC Scopus subject areas
- Earth and Planetary Sciences(all)
- Geology
- Earth and Planetary Sciences(all)
- Geochemistry and Petrology
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In: Chemical geology, Vol. 312-313, 18.06.2012, p. 27-46.
Research output: Contribution to journal › Article › Research › peer review
}
TY - JOUR
T1 - A profile of multiple sulfur isotopes through the Oman ophiolite
AU - Oeser, Martin
AU - Strauss, Harald
AU - Wolff, Paul Eric
AU - Koepke, Jürgen
AU - Peters, Marc
AU - Garbe-Schönberg, Dieter
AU - Dietrich, Marcel
PY - 2012/6/18
Y1 - 2012/6/18
N2 - The mineralogy, sulfur contents, and multiple sulfur isotopic compositions were determined for a complete section through the Oman ophiolite at the Wadi Gideah area located in the Wadi Tayin Massif (southern domain of the ophiolite complex) in order to characterize the various processes of sulfur cycling in the Oman ophiolite which is regarded as representing the best example of fast-spreading oceanic lithosphere on land. Upper crustal rocks (lavas and sheeted dikes) exhibit pervasive alteration due to intense circulation of seawater. Sulfate is the dominant sulfur phase, and sulfur (δ 34S) and oxygen isotopic compositions of sulfate suggest that sulfate is mainly derived from late Cretaceous seawater. 34S enrichments in sulfides (with respect to mantle sulfur) and low sulfide-S contents (<10ppm) reflect precipitation of hydrothermal sulfides followed by oxidation of sulfides during seafloor weathering. Clearly negative δ 34S values of CRS (Cr-reducible sulfur) in one pillow basalt sample indicate that microbial reduction of seawater sulfate occurred within the lavas during low-temperature alteration. Rocks of the gabbro/sheeted dike transition zone display variable δ 34S CRS values (between 0.5‰ and 5.5‰) paired with a wide range in sulfide-S contents (<1 to 489ppm). This reflects the dynamic nature of this interface between the hydrothermal circulation system of the upper crust and the magmatic system dominating the lower crust. Low δ 34S sulfate-S values indicate that sulfate in those rocks mainly results from oxidation of igneous sulfides. Although lower crustal rocks of the Oman ophiolite are affected by high-temperature alteration resulting in leaching and redistribution of sulfide-S, δ 34S values of monosulfide and disulfide minerals scatter around the value for mantle sulfur (0‰). δ 33S* values of CRS between -0.020‰ and -0.038‰ clearly differ from those of upper crustal rocks. Either this documents leaching processes operating in the lower crust, or lower crustal rocks have preserved a primary multiple sulfur isotopic composition that deviates from the postulated mantle value (δ 33S*=0.0‰).Rocks from the mantle sequence of the Oman ophiolite are affected by serpentinization under highly reducing conditions at low water-rock ratios followed by a further stage of serpentinization under oxidizing conditions at high water-rock ratios. The first stage of alteration results in loss of sulfur (sulfide-S contents <60ppm) paired with δ 34S sulfide values around 0‰. The second stage leads to 34S-enriched sulfide phases and also low sulfide-S contents. Sulfate-S contents vary from 5ppm to 213ppm and are generally higher than in the lower crust. Sulfur and oxygen isotopic compositions of sulfate suggest that sulfate is mainly derived from late Cretaceous seawater.
AB - The mineralogy, sulfur contents, and multiple sulfur isotopic compositions were determined for a complete section through the Oman ophiolite at the Wadi Gideah area located in the Wadi Tayin Massif (southern domain of the ophiolite complex) in order to characterize the various processes of sulfur cycling in the Oman ophiolite which is regarded as representing the best example of fast-spreading oceanic lithosphere on land. Upper crustal rocks (lavas and sheeted dikes) exhibit pervasive alteration due to intense circulation of seawater. Sulfate is the dominant sulfur phase, and sulfur (δ 34S) and oxygen isotopic compositions of sulfate suggest that sulfate is mainly derived from late Cretaceous seawater. 34S enrichments in sulfides (with respect to mantle sulfur) and low sulfide-S contents (<10ppm) reflect precipitation of hydrothermal sulfides followed by oxidation of sulfides during seafloor weathering. Clearly negative δ 34S values of CRS (Cr-reducible sulfur) in one pillow basalt sample indicate that microbial reduction of seawater sulfate occurred within the lavas during low-temperature alteration. Rocks of the gabbro/sheeted dike transition zone display variable δ 34S CRS values (between 0.5‰ and 5.5‰) paired with a wide range in sulfide-S contents (<1 to 489ppm). This reflects the dynamic nature of this interface between the hydrothermal circulation system of the upper crust and the magmatic system dominating the lower crust. Low δ 34S sulfate-S values indicate that sulfate in those rocks mainly results from oxidation of igneous sulfides. Although lower crustal rocks of the Oman ophiolite are affected by high-temperature alteration resulting in leaching and redistribution of sulfide-S, δ 34S values of monosulfide and disulfide minerals scatter around the value for mantle sulfur (0‰). δ 33S* values of CRS between -0.020‰ and -0.038‰ clearly differ from those of upper crustal rocks. Either this documents leaching processes operating in the lower crust, or lower crustal rocks have preserved a primary multiple sulfur isotopic composition that deviates from the postulated mantle value (δ 33S*=0.0‰).Rocks from the mantle sequence of the Oman ophiolite are affected by serpentinization under highly reducing conditions at low water-rock ratios followed by a further stage of serpentinization under oxidizing conditions at high water-rock ratios. The first stage of alteration results in loss of sulfur (sulfide-S contents <60ppm) paired with δ 34S sulfide values around 0‰. The second stage leads to 34S-enriched sulfide phases and also low sulfide-S contents. Sulfate-S contents vary from 5ppm to 213ppm and are generally higher than in the lower crust. Sulfur and oxygen isotopic compositions of sulfate suggest that sulfate is mainly derived from late Cretaceous seawater.
KW - Fast-spreading oceanic crust
KW - Multiple sulfur isotopes
KW - Oman ophiolite
KW - Sulfur cycling
UR - http://www.scopus.com/inward/record.url?scp=84860672216&partnerID=8YFLogxK
U2 - 10.1016/j.chemgeo.2012.04.008
DO - 10.1016/j.chemgeo.2012.04.008
M3 - Article
AN - SCOPUS:84860672216
VL - 312-313
SP - 27
EP - 46
JO - Chemical geology
JF - Chemical geology
SN - 0009-2541
ER -