Radon signature of CO2 flux constrains the depth of degassing: Furnas volcano (Azores, Portugal) versus Syabru-Bensi (Nepal Himalayas)

Girault, Frédéric; Viveiros, Fátima; Silva, Catarina; Thapa, Sandeep; Pacheco, Joana; Adhikari, Lok Bijaya; Bhattarai, Madhusudan; Koirala, Bharat Prasad; Agrinier, Pierre; France‐Lanord, Christian; Zanon, Vittorio; Vandemeulebrouck, Jean; Byrdina, Svetlana; Perrier, Frédéric

doi:10.1038/s41598-022-14653-5

Cited by 12 publications

(3 citation statements)

References 74 publications

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“…The potentially very fast (i.e., km/day rates) 74 , 75 rates of buoyant free phase gas migration in the subsurface can permit locally higher radon concentrations from depth (i.e. orders of magnitude greater than those observed in residences) 76 to reach the near subsurface, from whence radon diffuses upwards and outwards to surficial soil layers to generate an innately higher radon concentration in soil gas 76 . Rural residences could capture and retain greater amounts of alpha radiation emitting radionuclides (i.e.…”

Section: Resultsmentioning

confidence: 99%

Rural communities experience higher radon exposure versus urban areas, potentially due to drilled groundwater well annuli acting as unintended radon gas migration conduits

Khan,

Pearson,

Eldridge

et al. 2024

Sci Rep

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Repetitive, long-term inhalation of radioactive radon gas is one of the leading causes of lung cancer, with exposure differences being a function of geographic location, built environment, personal demographics, activity patterns, and decision-making. Here, we examine radon exposure disparities across the urban-to-rural landscape, based on 42,051 Canadian residential properties in 2034 distinct communities. People living in rural, lower population density communities experience as much as 31.2% greater average residential radon levels relative to urban equivalents, equating to an additional 26.7 Bq/m3 excess in geometric mean indoor air radon, and an additional 1 mSv/year in excess alpha radiation exposure dose rate to the lungs for occupants. Pairwise and multivariate analyses indicate that community-based radon exposure disparities are, in part, explained by increased prevalence of larger floorplan bungalows in rural areas, but that a majority of the effect is attributed to proximity to, but not water use from, drilled groundwater wells. We propose that unintended radon gas migration in the annulus of drilled groundwater wells provides radon migration pathways from the deeper subsurface into near-surface materials. Our findings highlight a previously under-appreciated determinant of radon-induced lung cancer risk, and support a need for targeted radon testing and reduction in rural communities.

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Section: Resultsmentioning

confidence: 99%

Rural communities experience higher radon exposure versus urban areas, potentially due to drilled groundwater well annuli acting as unintended radon gas migration conduits

Khan,

Pearson,

Eldridge

et al. 2024

Sci Rep

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“…In addition to emissions from living organisms, geogenic CO 2 release typically originates from volcanic-magmatic, mantle-related, or metamorphic sources. The quantity of accessible CO 2 release data has grown, prompting a timely assessment of the existing findings concerning one another [80]. The distribution map in Figure 29 shows the CO 2 emission in the HR volcanic field, highlighting the hotspots (red color) associated with active volcanic activities and their connection to geothermal sources.…”

Section: Indexmentioning

confidence: 99%

Machine Learning Techniques in Predicting Bottom Hole Temperature and Remote Sensing for Assessment of Geothermal Potential in the Kingdom of Saudi Arabia

Alqahtani,

Ehsan,

Abdulfarraj

et al. 2023

Sustainability

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The global demand for energy is increasing rapidly due to population growth, urbanization, and industrialization, as well as to meet the desire for a higher standard of living. However, environmental concerns, such as air pollution from fossil fuels, are becoming limiting factors for energy sources. Therefore, the appropriate and sustainable solution is to transition towards renewable energy sources to meet global energy demands by using environmentally friendly sources, such as geothermal. The Harrat Rahat volcanic field, located in the western region of the Kingdom of Saudi Arabia (KSA), gets more attention due to its geothermal potential as a viable site for geothermal energy exploration due to its high enthalpy. The prime objective of this study is to present up-to-date and comprehensive information on the utilization of borehole temperature and remote sensing data to identify the most prospective zones with significant geothermal activity favorable for exploration and drilling. A brief description of the selected wells and the methodology used to determine the petrophysical parameters relevant to the geothermal potential assessment are presented. Special emphasis is given to gamma-ray ray and temperature logs for calculating heat production and the geothermal gradient. The effectiveness of various machine learning techniques are assessed throughout this study for predicting the temperature-at-depth to evaluate the suitability of employing machine learning models for temperature prediction, and it is found that XG Boost provided excellent results. It can be observed that some linear anomalies can be traced in the NW, trending on the west side of the Harrat volcanic field based on magnetic data interpretation. The land surface temperature in 2021 exhibited higher temperatures compared to 2000, suggesting potential volcanic activity in the subsurface. It is concluded that the integration of remote sensing data with subsurface data provides the most reliable results.

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“…The latest research advancements on radon involve utilizing radon time series data to measure the radon flow (Alhmadi and Abdullah, 2021;Girault et al 2022;Haquin et al 2021;Muhammad and Külahcı 2022;Rafique et al 2022;Chen et al 2023;Lei et al 2023;Wang et al 2024). With underground systems, the prediction of radon's behaviour depends strongly on the identification of patterns hidden in the associated time series.…”

Section: Introductionmentioning

confidence: 99%

Fractal discrete fracture network modeling of radon gas concentration in underground tunnels under Książ Castle in Poland

Fijałkowska–Lichwa,

Ajayi

2024

Bull Eng Geol Environ

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The numerical modeling of radon concentrations in the fault zone of the underground excavations at Książ Castle was conducted using a stochastic Discrete Fracture Network (DFN) model. Due to the difficulties related with obtaining the exact fractures in a rock mass, the novel approach used in this study incorporates the stochastic model with known site data. The analysis utilized a dataset comprising long-term measurements of 222Rn activity concentration and geodetic measurements for twelve faults in the Książ unit. The parameters considered in the DFN model are: fracture length, Peclet number (Pe = 0.1 and 1.0, respectively), advection velocities (from 10–8 m/s to 10–6 m/s and from range from 10–7 m/s to 10–4 m/s, respectively), radon diffusion (D = 2.1 × 10–61/s), radon decay constant (λ = 1/s), and radon gas generation (q) along the fractures within the range of 1.5 × 10–3 Bq/m3·s to 3.5 × 10–3 Bq/m3·s. The calibration process obtained the best fit when the radon generation rate was uniformly distributed through the rock mass in addition to incorporating a higher value of radon generation rate (q = 3.0 × 10–3 Bq/m3·s) where elevated radon concentrations have been measured. The modeling results also confirmed that the radon generation rate should always be higher where elevated radon activity concentrations were measured regardless of the measurement period. For the indicated “area” the radon generation rate should be higher from 25% to 37.5% between May–October and 18.5% to 40% between November–April. The influence of fracture zones on the recorded radon activity concentrations was noticeable up to a depth of 15 m. Within this range, the highest values of 222Rn activity concentration, ranging from 1,600 Bq/m3 to 2,000 Bq/m3, were consistently observed regardless of the season. However, as the depth increased, the values of 222Rn activity concentration decreased from 800 Bq/m3 to 400 Bq/m3 and became more dispersed.

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Radon signature of CO2 flux constrains the depth of degassing: Furnas volcano (Azores, Portugal) versus Syabru-Bensi (Nepal Himalayas)

Cited by 12 publications

References 74 publications

Rural communities experience higher radon exposure versus urban areas, potentially due to drilled groundwater well annuli acting as unintended radon gas migration conduits

Rural communities experience higher radon exposure versus urban areas, potentially due to drilled groundwater well annuli acting as unintended radon gas migration conduits

Machine Learning Techniques in Predicting Bottom Hole Temperature and Remote Sensing for Assessment of Geothermal Potential in the Kingdom of Saudi Arabia

Fractal discrete fracture network modeling of radon gas concentration in underground tunnels under Książ Castle in Poland

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