Experimental investigation of the S and S-isotope distribution between H2O-S±Cl fluids and basaltic melts during decompression

Adrian Fiege; François Holtz; Harald Behrens; Charles W. Mandeville; Nobumichi Shimizu; Lars S. Crede; Jörg Göttlicher

doi:10.1016/j.chemgeo.2014.11.012

Details

Originalsprache	Englisch
Seiten (von - bis)	36-54
Seitenumfang	19
Fachzeitschrift	Chemical Geology
Jahrgang	393-394
Frühes Online-Datum	21 Nov. 2014
Publikationsstatus	Veröffentlicht - 30 Jan. 2015

Abstract

Decompression experiments (from 400 to 70MPa) were conducted to investigate sulfur (S) distribution and S-isotope fractionation between basaltic melts and coexisting fluids. Volatile-bearing [~3 to ~7wt.% water (H₂O), ~300 to ~1200ppmS, 0 to ~3600ppm chlorine (Cl)] basaltic glasses were used as starting materials. The MgO content in the melt was either ~1wt.% (Mg-poor basalt) or ~10wt.% (alkali basalt) to investigate the possible role of compositional changes in basaltic systems on fluid-melt distribution of S and S-isotopes. The experiments were performed in internally heated pressure vessels (IHPV) at 1050°C to 1250°C, variable oxygen fugacities (fO₂; ranging from log(fO₂/bar)~QFM to ~QFM+4; QFM=quartz-fayalite-magnetite buffer) and at a constant decompression rate (r) of 0.1MPa/s. The annealing time (t_A) at final pressure (p) and temperature (T) after decompression was varied from 0 to 5.5h to study the fluid-melt equilibration process.Sulfur and H₂O contents in the melt decreased significantly during decompression, while the Cl contents remained almost constant. No changes in H₂O and Cl content were observed with t_A, while S concentrations decreased slightly with t_A <2h; i.e., near-equilibrium fluid-melt conditions were reached within ~2h after decompression, even in experiments performed at the lowest T of 1050°C. Thus, fluid-melt partitioning coefficients of S (D_S^fl/m) were determined from experiments with t_A ≥2h.The MgO (~1 to ~10wt.%), H₂O (~3 to ~7wt.%) and Cl contents (<0.4wt.%) in the melt have no significant effect on D_S^fl/m. Consistent with previous studies we found that D_S^fl/m decreased strongly with increasing fO₂; e.g., at ~1200°C D_S^fl/m≈180 at QFM+1 and D_S^fl/m≈40 at QFM+4. A positive correlation was observed between D_S^fl/m and T in the range of 1150 to 1250°C at both oxidizing (QFM+4; D_S^fl/m=52±27 to 76±30) and intermediate (QFM+1.5; D_S^fl/m=94±20 to 209±80) redox conditions. Data compiled at 1050°C and relatively reducing conditions (~QFM; D_S^fl/m=58±18) indicate that the trends may be extrapolated to lower T, at least for intermediate to reducing conditions (~QFM+1.5 to ~QFM).The S-isotope composition in glasses of selected samples was measured by secondary ion mass spectrometry (SIMS). Gas-melt isotopic fractionation factors (α_fl-m) were calculated via mass balance. At 1200°C an average α_fl-m of 0.9981±0.0015 was determined for oxidizing conditions (~QFM+4), while an average α_fl-m of 1.0025±0.0010 was found for fairly reducing conditions (~QFM+1). Furthermore, at lower T (1050°C) an average α_fl-m of 1.0037±0.0009 was determined for reducing conditions (~QFM). The data showed that equilibrium fractionation effects during closed-system degassing of basaltic melts at T relevant for magmatic systems (1050 to 1250°C) can induce a S-isotope fluid-melt fractionation of about +4‰ in relatively reduced systems and of about -2‰ in relatively oxidized systems.The reported experimental results are valuable for the interpretation of S and S-isotope signature in magmatic systems (e.g., in volcanic gasses or melt inclusions) and will help to elucidate, for instance, volatile transport processes across subduction zones and Earth's S cycle.

ASJC Scopus Sachgebiete

Erdkunde und Planetologie (insg.)
Geologie
Erdkunde und Planetologie (insg.)
Geochemie und Petrologie

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Experimental investigation of the S and S-isotope distribution between H₂O-S±Cl fluids and basaltic melts during decompression. / Fiege, Adrian; Holtz, François; Behrens, Harald et al.
in: Chemical Geology, Jahrgang 393-394, 30.01.2015, S. 36-54.

Publikation: Beitrag in Fachzeitschrift › Artikel › Forschung › Peer-Review

Fiege, A, Holtz, F, Behrens, H, Mandeville, CW, Shimizu, N, Crede, LS & Göttlicher, J 2015, 'Experimental investigation of the S and S-isotope distribution between H₂O-S±Cl fluids and basaltic melts during decompression', Chemical Geology, Jg. 393-394, S. 36-54. https://doi.org/10.1016/j.chemgeo.2014.11.012

Fiege, A., Holtz, F., Behrens, H., Mandeville, C. W., Shimizu, N., Crede, L. S., & Göttlicher, J. (2015). Experimental investigation of the S and S-isotope distribution between H₂O-S±Cl fluids and basaltic melts during decompression. Chemical Geology, 393-394, 36-54. https://doi.org/10.1016/j.chemgeo.2014.11.012

Fiege A, Holtz F, Behrens H, Mandeville CW, Shimizu N, Crede LS et al. Experimental investigation of the S and S-isotope distribution between H₂O-S±Cl fluids and basaltic melts during decompression. Chemical Geology. 2015 Jan 30;393-394:36-54. Epub 2014 Nov 21. doi: 10.1016/j.chemgeo.2014.11.012

Fiege, Adrian ; Holtz, François ; Behrens, Harald et al. / Experimental investigation of the S and S-isotope distribution between H₂O-S±Cl fluids and basaltic melts during decompression. in: Chemical Geology. 2015 ; Jahrgang 393-394. S. 36-54.

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@article{3d2389d6ea204c64bf7d37e3e75d4c3c,

title = "Experimental investigation of the S and S-isotope distribution between H2O-S±Cl fluids and basaltic melts during decompression",

abstract = "Decompression experiments (from 400 to 70MPa) were conducted to investigate sulfur (S) distribution and S-isotope fractionation between basaltic melts and coexisting fluids. Volatile-bearing [~3 to ~7wt.% water (H2O), ~300 to ~1200ppmS, 0 to ~3600ppm chlorine (Cl)] basaltic glasses were used as starting materials. The MgO content in the melt was either ~1wt.% (Mg-poor basalt) or ~10wt.% (alkali basalt) to investigate the possible role of compositional changes in basaltic systems on fluid-melt distribution of S and S-isotopes. The experiments were performed in internally heated pressure vessels (IHPV) at 1050°C to 1250°C, variable oxygen fugacities (fO2; ranging from log(fO2/bar)~QFM to ~QFM+4; QFM=quartz-fayalite-magnetite buffer) and at a constant decompression rate (r) of 0.1MPa/s. The annealing time (tA) at final pressure (p) and temperature (T) after decompression was varied from 0 to 5.5h to study the fluid-melt equilibration process.Sulfur and H2O contents in the melt decreased significantly during decompression, while the Cl contents remained almost constant. No changes in H2O and Cl content were observed with tA, while S concentrations decreased slightly with tA <2h; i.e., near-equilibrium fluid-melt conditions were reached within ~2h after decompression, even in experiments performed at the lowest T of 1050°C. Thus, fluid-melt partitioning coefficients of S (DSfl/m) were determined from experiments with tA ≥2h.The MgO (~1 to ~10wt.%), H2O (~3 to ~7wt.%) and Cl contents (<0.4wt.%) in the melt have no significant effect on DSfl/m. Consistent with previous studies we found that DSfl/m decreased strongly with increasing fO2; e.g., at ~1200°C DSfl/m≈180 at QFM+1 and DSfl/m≈40 at QFM+4. A positive correlation was observed between DSfl/m and T in the range of 1150 to 1250°C at both oxidizing (QFM+4; DSfl/m=52±27 to 76±30) and intermediate (QFM+1.5; DSfl/m=94±20 to 209±80) redox conditions. Data compiled at 1050°C and relatively reducing conditions (~QFM; DSfl/m=58±18) indicate that the trends may be extrapolated to lower T, at least for intermediate to reducing conditions (~QFM+1.5 to ~QFM).The S-isotope composition in glasses of selected samples was measured by secondary ion mass spectrometry (SIMS). Gas-melt isotopic fractionation factors (αfl-m) were calculated via mass balance. At 1200°C an average αfl-m of 0.9981±0.0015 was determined for oxidizing conditions (~QFM+4), while an average αfl-m of 1.0025±0.0010 was found for fairly reducing conditions (~QFM+1). Furthermore, at lower T (1050°C) an average αfl-m of 1.0037±0.0009 was determined for reducing conditions (~QFM). The data showed that equilibrium fractionation effects during closed-system degassing of basaltic melts at T relevant for magmatic systems (1050 to 1250°C) can induce a S-isotope fluid-melt fractionation of about +4‰ in relatively reduced systems and of about -2‰ in relatively oxidized systems.The reported experimental results are valuable for the interpretation of S and S-isotope signature in magmatic systems (e.g., in volcanic gasses or melt inclusions) and will help to elucidate, for instance, volatile transport processes across subduction zones and Earth's S cycle.",

keywords = "Basalt, Chlorine, Magma degassing, Sulfur, Sulfur fluid-melt distribution, Sulfur isotope fractionation",

author = "Adrian Fiege and Fran{\c c}ois Holtz and Harald Behrens and Mandeville, {Charles W.} and Nobumichi Shimizu and Crede, {Lars S.} and J{\"o}rg G{\"o}ttlicher",

year = "2015",

month = jan,

day = "30",

doi = "10.1016/j.chemgeo.2014.11.012",

language = "English",

volume = "393-394",

pages = "36--54",

journal = "Chemical Geology",

issn = "0009-2541",

publisher = "Elsevier",

}

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TY - JOUR

T1 - Experimental investigation of the S and S-isotope distribution between H2O-S±Cl fluids and basaltic melts during decompression

AU - Fiege, Adrian

AU - Holtz, François

AU - Behrens, Harald

AU - Mandeville, Charles W.

AU - Shimizu, Nobumichi

AU - Crede, Lars S.

AU - Göttlicher, Jörg

PY - 2015/1/30

Y1 - 2015/1/30

N2 - Decompression experiments (from 400 to 70MPa) were conducted to investigate sulfur (S) distribution and S-isotope fractionation between basaltic melts and coexisting fluids. Volatile-bearing [~3 to ~7wt.% water (H2O), ~300 to ~1200ppmS, 0 to ~3600ppm chlorine (Cl)] basaltic glasses were used as starting materials. The MgO content in the melt was either ~1wt.% (Mg-poor basalt) or ~10wt.% (alkali basalt) to investigate the possible role of compositional changes in basaltic systems on fluid-melt distribution of S and S-isotopes. The experiments were performed in internally heated pressure vessels (IHPV) at 1050°C to 1250°C, variable oxygen fugacities (fO2; ranging from log(fO2/bar)~QFM to ~QFM+4; QFM=quartz-fayalite-magnetite buffer) and at a constant decompression rate (r) of 0.1MPa/s. The annealing time (tA) at final pressure (p) and temperature (T) after decompression was varied from 0 to 5.5h to study the fluid-melt equilibration process.Sulfur and H2O contents in the melt decreased significantly during decompression, while the Cl contents remained almost constant. No changes in H2O and Cl content were observed with tA, while S concentrations decreased slightly with tA <2h; i.e., near-equilibrium fluid-melt conditions were reached within ~2h after decompression, even in experiments performed at the lowest T of 1050°C. Thus, fluid-melt partitioning coefficients of S (DSfl/m) were determined from experiments with tA ≥2h.The MgO (~1 to ~10wt.%), H2O (~3 to ~7wt.%) and Cl contents (<0.4wt.%) in the melt have no significant effect on DSfl/m. Consistent with previous studies we found that DSfl/m decreased strongly with increasing fO2; e.g., at ~1200°C DSfl/m≈180 at QFM+1 and DSfl/m≈40 at QFM+4. A positive correlation was observed between DSfl/m and T in the range of 1150 to 1250°C at both oxidizing (QFM+4; DSfl/m=52±27 to 76±30) and intermediate (QFM+1.5; DSfl/m=94±20 to 209±80) redox conditions. Data compiled at 1050°C and relatively reducing conditions (~QFM; DSfl/m=58±18) indicate that the trends may be extrapolated to lower T, at least for intermediate to reducing conditions (~QFM+1.5 to ~QFM).The S-isotope composition in glasses of selected samples was measured by secondary ion mass spectrometry (SIMS). Gas-melt isotopic fractionation factors (αfl-m) were calculated via mass balance. At 1200°C an average αfl-m of 0.9981±0.0015 was determined for oxidizing conditions (~QFM+4), while an average αfl-m of 1.0025±0.0010 was found for fairly reducing conditions (~QFM+1). Furthermore, at lower T (1050°C) an average αfl-m of 1.0037±0.0009 was determined for reducing conditions (~QFM). The data showed that equilibrium fractionation effects during closed-system degassing of basaltic melts at T relevant for magmatic systems (1050 to 1250°C) can induce a S-isotope fluid-melt fractionation of about +4‰ in relatively reduced systems and of about -2‰ in relatively oxidized systems.The reported experimental results are valuable for the interpretation of S and S-isotope signature in magmatic systems (e.g., in volcanic gasses or melt inclusions) and will help to elucidate, for instance, volatile transport processes across subduction zones and Earth's S cycle.

AB - Decompression experiments (from 400 to 70MPa) were conducted to investigate sulfur (S) distribution and S-isotope fractionation between basaltic melts and coexisting fluids. Volatile-bearing [~3 to ~7wt.% water (H2O), ~300 to ~1200ppmS, 0 to ~3600ppm chlorine (Cl)] basaltic glasses were used as starting materials. The MgO content in the melt was either ~1wt.% (Mg-poor basalt) or ~10wt.% (alkali basalt) to investigate the possible role of compositional changes in basaltic systems on fluid-melt distribution of S and S-isotopes. The experiments were performed in internally heated pressure vessels (IHPV) at 1050°C to 1250°C, variable oxygen fugacities (fO2; ranging from log(fO2/bar)~QFM to ~QFM+4; QFM=quartz-fayalite-magnetite buffer) and at a constant decompression rate (r) of 0.1MPa/s. The annealing time (tA) at final pressure (p) and temperature (T) after decompression was varied from 0 to 5.5h to study the fluid-melt equilibration process.Sulfur and H2O contents in the melt decreased significantly during decompression, while the Cl contents remained almost constant. No changes in H2O and Cl content were observed with tA, while S concentrations decreased slightly with tA <2h; i.e., near-equilibrium fluid-melt conditions were reached within ~2h after decompression, even in experiments performed at the lowest T of 1050°C. Thus, fluid-melt partitioning coefficients of S (DSfl/m) were determined from experiments with tA ≥2h.The MgO (~1 to ~10wt.%), H2O (~3 to ~7wt.%) and Cl contents (<0.4wt.%) in the melt have no significant effect on DSfl/m. Consistent with previous studies we found that DSfl/m decreased strongly with increasing fO2; e.g., at ~1200°C DSfl/m≈180 at QFM+1 and DSfl/m≈40 at QFM+4. A positive correlation was observed between DSfl/m and T in the range of 1150 to 1250°C at both oxidizing (QFM+4; DSfl/m=52±27 to 76±30) and intermediate (QFM+1.5; DSfl/m=94±20 to 209±80) redox conditions. Data compiled at 1050°C and relatively reducing conditions (~QFM; DSfl/m=58±18) indicate that the trends may be extrapolated to lower T, at least for intermediate to reducing conditions (~QFM+1.5 to ~QFM).The S-isotope composition in glasses of selected samples was measured by secondary ion mass spectrometry (SIMS). Gas-melt isotopic fractionation factors (αfl-m) were calculated via mass balance. At 1200°C an average αfl-m of 0.9981±0.0015 was determined for oxidizing conditions (~QFM+4), while an average αfl-m of 1.0025±0.0010 was found for fairly reducing conditions (~QFM+1). Furthermore, at lower T (1050°C) an average αfl-m of 1.0037±0.0009 was determined for reducing conditions (~QFM). The data showed that equilibrium fractionation effects during closed-system degassing of basaltic melts at T relevant for magmatic systems (1050 to 1250°C) can induce a S-isotope fluid-melt fractionation of about +4‰ in relatively reduced systems and of about -2‰ in relatively oxidized systems.The reported experimental results are valuable for the interpretation of S and S-isotope signature in magmatic systems (e.g., in volcanic gasses or melt inclusions) and will help to elucidate, for instance, volatile transport processes across subduction zones and Earth's S cycle.

KW - Basalt

KW - Chlorine

KW - Magma degassing

KW - Sulfur

KW - Sulfur fluid-melt distribution

KW - Sulfur isotope fractionation

UR - http://www.scopus.com/inward/record.url?scp=84949115226&partnerID=8YFLogxK

U2 - 10.1016/j.chemgeo.2014.11.012

DO - 10.1016/j.chemgeo.2014.11.012

M3 - Article

AN - SCOPUS:84949115226

VL - 393-394

SP - 36

EP - 54

JO - Chemical Geology

JF - Chemical Geology

SN - 0009-2541

ER -

Research@Leibniz University

Experimental investigation of the S and S-isotope distribution between H₂O-S±Cl fluids and basaltic melts during decompression

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