Radon, Health and Natural Hazards
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Radon and carbon dioxide around remote Himalayan thermal springs
Published:January 01, 2018
Frédéric Girault, Bharat Prasad Koirala, Mukunda Bhattarai, Frédéric Perrier, 2018. "Radon and carbon dioxide around remote Himalayan thermal springs", Radon, Health and Natural Hazards, G. K. Gillmore, F. E. Perrier, R. G. M. Crockett
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Radon-222 and carbon dioxide (CO2) emissions were studied around four remote Nepalese thermal springs near the Main Central Thrust: Timure and Chilime in the upper Trisuli Valley, central Nepal; and Sulighad and Tarakot in Lower Dolpo, western Nepal. A total of 279 radon fluxes and 670 CO2 fluxes were measured on the ground, complemented by radon concentration measurements in soil and water, and assisted by thermal infrared imaging. In Lower Dolpo, mean radon fluxes ranging from 270×10−3 to 450×10−3 Bq m−2 s−1, radon concentration in water greater than 100 Bq l−1, low mean CO2 fluxes (18–32 g m−2 day−1), and integrated radon and CO2 discharges of 70–180 Bq s−1 and (2.3–3.8)×10−3 mol s−1, respectively, suggest shallow-water-dominated transport with simultaneous radon and CO2 degassing from the hydrothermal water. In the upper Trisuli Valley, mean radon fluxes ranging from 140×10−3 to 570×10−3 Bq m−2 s−1, larger mean CO2 fluxes that range from 430 to 2930 g m−2 day−1, radon concentration in water of less than 6 Bq l−1, and integrated radon and CO2 discharges of 290–840 Bq s−1 and (390–830)×10−3 mol s−1, respectively, indicate fast gas-dominated transport of deep metamorphic-origin CO2 charged in radon along a fault network. Radon can thus give precious information on the gas transport properties of the shallow continental crust.
Supplementary material: Additional radon and carbon dioxide flux measurement profiles are available at https://doi.org/10.6084/m9.figshare.c.3582128