Sulfur isotopes in Icelandic thermal fluids

Multiple sulfur isotope compositions of thermal fluids from Iceland were measured in order to evaluate the sources and reactions of sulfur and sulfur isotope fractionation in geothermal systems at Icelandic divergent plate boundaries, characterized by MORB-like basalts. The geothermal systems studie...

Full description

Saved in:
Bibliographic Details
Published inJournal of volcanology and geothermal research Vol. 346; pp. 161 - 179
Main Authors Gunnarsson-Robin, Jóhann, Stefánsson, Andri, Ono, Shuhei, Torssander, Peter
Format Journal Article
LanguageEnglish
Published Elsevier B.V 15.10.2017
Subjects
Online AccessGet full text

Cover

Loading…
More Information
Summary:Multiple sulfur isotope compositions of thermal fluids from Iceland were measured in order to evaluate the sources and reactions of sulfur and sulfur isotope fractionation in geothermal systems at Icelandic divergent plate boundaries, characterized by MORB-like basalts. The geothermal systems studied had a wide range of reservoir temperatures of 56–296°C and Cl concentrations of 18–21,000ppm. Dissolved sulfide (∑S−II) and SO4 concentrations in liquid water measured <0.01–165ppm and 1.3–300ppm, respectively, and H2S(g) concentrations in the vapor 4.9–2000 ppm. The δ34S and Δ33S values for different phases and oxidation states were highly variable: δ34S∑S−II=−11.6 to 10.5‰ (n=99), ∆33S∑S−II=−0.12 to 0.00‰ (n=45), δ34SSO4=−1.0 to 24.9‰ (n=125), ∆33SSO4=−0.04 to 0.02‰ (n=50), δ34SH2S(g)=−2.6 to 5.9‰ (n=112) and ∆33SH2S(g)=−0.03 to 0.00‰ (n=56). The multiple sulfur isotope values of the thermal fluids are interpreted to reflect various sources of sulfur in the fluids, as well as isotope fractionation occurring within the geothermal systems associated with fluid-rock interaction, boiling and oxidation and reduction reactions. The results of isotope geochemical modeling demonstrate that the sources of S−II in the thermal fluid are leaching of basalt (MORB) and seawater SO4 reduction for saline systems with insignificant magma gas input, and that the observed ranges of δ34S and Δ33S for ∑S−II and H2S(g) reflect isotope fractionation between minerals and aqueous and gaseous species upon fluid-rock interaction and boiling. The sources of SO4 are taken to be multiple, including oxidation of S−II originating from basalt, leaching of SVI from the basalts and the seawater itself in the case of saline systems. In low-temperature fluids, the δ34S and Δ33S values reflect the various sources of sulfur. For high-temperature fluids, fluid-rock interaction, ∑S−II oxidation and SO4 reduction and sulfide and sulfate mineral formation result in a large range of δ34S and Δ33S values for ∑S−II and SO4 in the fluids, highlighting the importance and effects of chemical reactions on the isotope systematics of reactive elements like sulfur. Such effects needed to be quantified in order to reveal the various sources of an element. •A dataset of S-isotope values (δ34S, Δ33S, Δ36S) from icelandic fluids is presented.•Main source of sulfur in Icelandic thermal waters from water-rock interaction.•Novel geochemical modeling techniques used to trace sulfur sources.
ISSN:0377-0273
1872-6097
1872-6097
DOI:10.1016/j.jvolgeores.2017.01.021