Journal
GEOCHEMISTRY GEOPHYSICS GEOSYSTEMS
Volume 15, Issue 12, Pages 4885-4904Publisher
AMER GEOPHYSICAL UNION
DOI: 10.1002/2014GC005327
Keywords
soil gas flux; carbon dioxide; stable isotope analysis; sequential Gaussian simulation; mass and heat flow assessment
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Funding
- UC-MRP Source 2 Surface research program
- Ministry of Science and Innovation's Foundation for Research, Science, & Technology through a TechNZ Scholarship
- University of Canterbury's Mason trust
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The quantification of heat and mass flow between deep reservoirs and the surface is important for understanding magmatic and hydrothermal systems. Here, we use high-resolution measurement of carbon dioxide flux (CO2) and heat flow at the surface to characterize the mass (CO2 and steam) and heat released to the atmosphere from two magma-hydrothermal systems. Our soil gas and heat flow surveys at Rotokawa and White Island in the Taup Volcanic Zone, New Zealand, include over 3000 direct measurements of CO2 and soil temperature and 60 carbon isotopic values on soil gases. Carbon dioxide flux was separated into background and magmatic/hydrothermal populations based on the measured values and isotopic characterization. Total CO2 emission rates (sigma CO2) of 44184 t d(-1) and 12418 t d(-1) were calculated for Rotokawa (2.9 km(2)) and for the crater floor at White Island (0.3 km(2)), respectively. The total CO2 emissions differ from previously published values by +386 t d(-1) at Rotokawa and +25 t d(-1) at White Island, demonstrating that earlier research underestimated emissions by 700% (Rotokawa) and 25% (White Island). These differences suggest that soil CO2 emissions facilitate more robust estimates of the thermal energy and mass flux in geothermal systems than traditional approaches. Combining the magmatic/hydrothermal-sourced CO2 emission (constrained using stable isotopes) with reservoir H2O:CO2 mass ratios and the enthalpy of evaporation, the surface expression of thermal energy release for the Rotokawa hydrothermal system (226 MWt) is 10 times greater than the White Island crater floor (22.5 MWt).
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