Noble gas and N(2) compositions have been determined in paleofluids of core samples from geothermal wells in the Larderello area, Italy. The results were coupled with hydrogen and carbon isotope compositions of similar fluids from an independent batch of samples to provide constraints on the origin of the fluids. The fluids trapped during early-stage hydrothermal circulation are characterized by relatively high (40)Ar/(36)Ar and N(2)/Ar ratios (332 <=(40)Ar/(36)Ar <= 564 and 248 <= N(2)/Ar <= 4197, respectively) and indicate the presence of radiogenic (40)Ar and excess N2 when compared to air/asw (air saturated water). The fluid inclusions related to late-stage hydrothermal activity show low N(2)/Ar and (40)Ar/(36)Ar ratios (309 <=(40)Ar/(36)Ar <= 354 and 47 < N2/Ar < 66, respectively), similar to present-day geothermal fluids. The delta D values of the inclusion fluids range from -53 parts per thousand to -85 parts per thousand, indicating that the fluids were derived from mixing of water-rich components, probably from a shallow reservoir similar in composition to present-day meteoric waters, and fluids from a deeper reservoir. The R/R(a) ratios (up to 3.2) of the paleofluids and present-day fluids suggest a deep He contribution at Larderello. The delta(13)C values for CO(2) trapped during early-stage activity (-3.8 parts per thousand to 0.5 parts per thousand) were produced by carbonate country rock volatilisation; delta(13)C values as low as -17 parts per thousand were measured in inclusion fluids related to late-stage circulation, and were likely produced by oxidation of organic matter at shallow depths. (c) 2005 Elsevier B.V. All rights reserved.

Stable isotope and noble gas isotope compositions of inclusion fluids from Larderello geothermal field (Italy): Constraints to fluid origin and mixing processes

Dallai L;Magro G;Ruggieri G
2005

Abstract

Noble gas and N(2) compositions have been determined in paleofluids of core samples from geothermal wells in the Larderello area, Italy. The results were coupled with hydrogen and carbon isotope compositions of similar fluids from an independent batch of samples to provide constraints on the origin of the fluids. The fluids trapped during early-stage hydrothermal circulation are characterized by relatively high (40)Ar/(36)Ar and N(2)/Ar ratios (332 <=(40)Ar/(36)Ar <= 564 and 248 <= N(2)/Ar <= 4197, respectively) and indicate the presence of radiogenic (40)Ar and excess N2 when compared to air/asw (air saturated water). The fluid inclusions related to late-stage hydrothermal activity show low N(2)/Ar and (40)Ar/(36)Ar ratios (309 <=(40)Ar/(36)Ar <= 354 and 47 < N2/Ar < 66, respectively), similar to present-day geothermal fluids. The delta D values of the inclusion fluids range from -53 parts per thousand to -85 parts per thousand, indicating that the fluids were derived from mixing of water-rich components, probably from a shallow reservoir similar in composition to present-day meteoric waters, and fluids from a deeper reservoir. The R/R(a) ratios (up to 3.2) of the paleofluids and present-day fluids suggest a deep He contribution at Larderello. The delta(13)C values for CO(2) trapped during early-stage activity (-3.8 parts per thousand to 0.5 parts per thousand) were produced by carbonate country rock volatilisation; delta(13)C values as low as -17 parts per thousand were measured in inclusion fluids related to late-stage circulation, and were likely produced by oxidation of organic matter at shallow depths. (c) 2005 Elsevier B.V. All rights reserved.
2005
Istituto di Geoscienze e Georisorse - IGG - Sede Pisa
Fluid inclusions; Larderello; Noble gases; Stable isotopes
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/149836
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