Your search keyword '"geogenic radon potential"' showing total 48 results

1. RadonPotential: An interactive web application for radon potential prediction under different climates and soil textures

Author

Galiana-Merino, Juan Jose, Gil-Oncina, Sara, Valdes-Abellan, Javier, Soler-Llorens, Juan Luis, and Benavente, David

Published

2024

2. Radon Dynamics in Granite and Calcareous Soils: Long-Term Experiments in a Semi-Arid Context

Author

Sara Gil-Oncina, Concepcion Pla, Javier Valdes-Abellan, Angel Fernandez-Cortes, and David Benavente

Subjects

geogenic radon potential, soil moisture, gas permeability, forced conditions experiment, continuous radon time series, environmental radioactivity, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Radon in soil poses a significant health risk when it accumulates inside dwellings. The estimation of radon potential is a difficult task due to the complex dynamics of radon within soil and its relations with the weather. This research focuses on the variability of radon activity, driven by environmental changes, assessed in two loam soils (loamy sand–granite soil and silty clay loam-calcareous soil) with different radium contents. We conducted an experiment with teow soil columns in a semi-controlled outdoor laboratory, in a warm semi-arid climate. We also examined the consequences of abundant rainfall on radon activity through artificial soil water content (SWC) experiment conditions. Statistical analyses reveal that SWC is the most significant parameter influencing radon activity in these experiments. Radon is proportional to SWC and inversely proportional to temperature, evapotranspiration, and pressure in both soils, while wind is negatively related only in the loamy sand soil. Based on our findings, we modelled radon potential considering different soils and climatic contexts. SWC influences radon potential by changing radon emanation, activity, and permeability, depending on the local soil texture and radium concentration.

Published

2024

3. Artificial neural network modeling of soil gas radon concentration on different lithologies for Southwest Nigeria

Author

Idowu Peter Farai, Joseph Ademola Fajemiroye, Olatunde Michael Oni, and Abraham Adewale Aremu

Subjects

Soil gas radon, Soil air permeability, Geogenic radon potential, Artificial neural network, RAD 7, Medical physics. Medical radiology. Nuclear medicine, R895-920, Nuclear engineering. Atomic power, TK9001-9401

Abstract

Radon is a radioactive gas and a leading cause of lung cancer among non-smokers. An indicator of the level of risk associated with radon inhalation is the Geogenic Radon Potential (GRP) - a function of the soil gas radon concentration and the soil air permeability. Data is scarce on the variation of soil gas radon and GRP across different geological formations in southwest Nigeria. This study was designed to measure and develop a generalized predictive model for soil gas radon concentration and hence GRP on different bedrocks in southwest Nigeria. Soil gas radon was measured with a RAD 7 radon detector in 150 sites randomly selected over 20 major bedrocks. Soil air permeability was derived from soil saturated hydraulic conductivity measured using a constant head permeameter on undisturbed soil samples from the same sites. The GRP was obtained using Neznal relation. A 2 × 8 x 1 Artificial Neural Network (ANN) configuration culminated in the generation of a tested and validated predictive model for soil gas radon in southwest Nigeria. For the 150 sites, the range of values for soil gas radon concentration was 0.28–47.59 kBqm−3 and a mean of 10.39 ± 12.59 kBqm−3; soils on granitic bedrocks had the highest mean soil gas radon concentration (16.89 kBqm−3) and highest mean GRP (13.71). Sediments had the highest mean soil air permeability of 39.84 × 10−12 m2. Using Neznal classification, 75.30% of the sites were of low radon hazard rating. The developed predictive ANN model had a Goodness-of-Prediction (G) of 73.53%, Average Validation Error (AVE) of 0.073, Mean Bias Error (MBE) of 0.42, and Root Mean Square Error (RMSE) of 4.62kBqm−3, respectively. The model, validated using standard procedure had G, MBE, AVE, and RMSE of 86.49%, 0.61, 0.17, and 1.65kBqm−3, respectively which is an indication of good model performance.

Published

2022

4. Determining the Geogenic Radon Potential in Different Layouts and Numbers of Points.

Author

Lupulescu, Alexandru, Baciu, Călin, Dicu, Tiberius, Burghele, Bety-Denissa, and Cucoș, Alexandra Laura

Subjects

*RADON, *SOIL permeability, *SOIL air, *SEDIMENTARY rocks, *NATURAL radioactivity, *TIME measurements

Abstract

The geogenic radon potential is primarily controlled by the geological characteristics of the site, such as the rock type and structural elements, as well as the permeability of the soil. Depending on the scope of the survey, the geogenic radon potential can be mapped based on measurements conducted in the field at various resolutions. Detailed surveys are generally labour-intensive and time-consuming. Therefore, a balance should be reached between the desired level of precision and the required amount of effort, delivering the best results with the least number of resources. The international literature describes a variety of surveying techniques. This study was undertaken in a region of the central zone of the Poiana Rusca Mountains (Southern Carpathians, Romania) that contains several metamorphic, volcanic, and sedimentary rock types. The primary objective of the study is to compare alternative sampling point configurations, which vary in number and arrangement. The objective was to achieve the most accurate representation of the calculated geogenic radon potential while limiting the number of measurements and the time and effort associated with them. Radon activity concentration and soil permeability data were collected from 34 locations using seven alternative layouts of the sampling points. The proposed layouts were based on various configurations of fifteen, nine, five, and three sampling points. Locally, in some of the metamorphic units and in the regions containing sedimentary deposits with volcanic intercalations, the geogenic radon potential was found to be elevated. The results indicate that the three-measuring-point configuration is acceptable for general geogenic radon potential surveys. [ABSTRACT FROM AUTHOR]

Published

2023

5. Air Quality Monitoring for Preventive Conservation of the Built Heritage Deteriorated by Salt Crystallization.

Author

Benavente, David, Pla, Concepción, Gil-Oncina, Sara, Ruiz, Maria Candela, Blanco-Quintero, Idael Francisco, Huesca-Tortosa, Jose Antonio, Spairani-Berrio, Yolanda, and Sanchez-Moral, Sergio

Subjects

AIR quality monitoring, CONSERVATION & restoration, PRECIPITATION (Chemistry), CRYSTALLIZATION, PERITECTIC reactions, MICROBIOLOGICAL aerosols, CRYSTAL whiskers, DISSOLUTION (Chemistry)

Abstract

The Santo Domingo Diocesan School (Orihuela, SE Spain) is a singular case study that relates air quality monitoring and stone conservation. The monument suffers severe damage due to salt crystallization by rising damp, which is related to the indoor environment dynamics, high groundwater salt content, and microstructure, the building's porous stone (biocalcarenite). Results revealed that 222Rn concentration in indoor air is low due to the building's high ventilation rate, despite the medium-low geogenic radon potential in the area. Wavelets analysis showed that ventilation is caused by outdoor and indoor temperature variations and directly affects the 222Rn and CO2 dynamics inside the church. CO2, as well as relative humidity (RH), presented periodicities with intermediate frequencies (5–8 days) related to visits. These RH and temperature (T) variations intensified the salt damage by increasing the frequency of dissolution-crystallization cycles. The mineralogical characterization and geochemical calculations concluded that chlorides (halite and sylvite), sulfates (thenardite, epsomite, hexahydrite and aphthitalite) and nitrates (niter) present from dissolution forms to whiskers and hopper-type morphologies. This indicates high saturation values and, therefore, higher crystallization pressure values within the porous media of the biocalcarenite. On the contrary, the near-equilibrium crystal shape and incongruent precipitation reaction for humberstonite suggest a lower alteration for this salt on the building stone. [ABSTRACT FROM AUTHOR]

Published

2022

6. Radon Dynamics in Granite and Calcareous Soils: Long-Term Experiments in a Semi-Arid Context

Author

Universidad de Alicante. Departamento de Ciencias de la Tierra y del Medio Ambiente, Universidad de Alicante. Departamento de Ingeniería Civil, Gil-Oncina, Sara, Pla, Concepción, Valdes-Abellan, Javier, Fernández Cortés, Ángel, Benavente, David, Universidad de Alicante. Departamento de Ciencias de la Tierra y del Medio Ambiente, Universidad de Alicante. Departamento de Ingeniería Civil, Gil-Oncina, Sara, Pla, Concepción, Valdes-Abellan, Javier, Fernández Cortés, Ángel, and Benavente, David

Abstract

Radon in soil poses a significant health risk when it accumulates inside dwellings. The estimation of radon potential is a difficult task due to the complex dynamics of radon within soil and its relations with the weather. This research focuses on the variability of radon activity, driven by environmental changes, assessed in two loam soils (loamy sand–granite soil and silty clay loam-calcareous soil) with different radium contents. We conducted an experiment with teow soil columns in a semi-controlled outdoor laboratory, in a warm semi-arid climate. We also examined the consequences of abundant rainfall on radon activity through artificial soil water content (SWC) experiment conditions. Statistical analyses reveal that SWC is the most significant parameter influencing radon activity in these experiments. Radon is proportional to SWC and inversely proportional to temperature, evapotranspiration, and pressure in both soils, while wind is negatively related only in the loamy sand soil. Based on our findings, we modelled radon potential considering different soils and climatic contexts. SWC influences radon potential by changing radon emanation, activity, and permeability, depending on the local soil texture and radium concentration.

Published

2024

7. RadonPotential: An interactive web application for radon potential prediction under different climates and soil textures

Author

Universidad de Alicante. Departamento de Física, Ingeniería de Sistemas y Teoría de la Señal, Universidad de Alicante. Departamento de Ciencias de la Tierra y del Medio Ambiente, Universidad de Alicante. Departamento de Ingeniería Civil, Universidad de Alicante. Instituto Universitario de Física Aplicada a las Ciencias y las Tecnologías, Galiana-Merino, Juan José, Gil-Oncina, Sara, Valdes-Abellan, Javier, Soler Llorens, Juan Luis, Benavente, David, Universidad de Alicante. Departamento de Física, Ingeniería de Sistemas y Teoría de la Señal, Universidad de Alicante. Departamento de Ciencias de la Tierra y del Medio Ambiente, Universidad de Alicante. Departamento de Ingeniería Civil, Universidad de Alicante. Instituto Universitario de Física Aplicada a las Ciencias y las Tecnologías, Galiana-Merino, Juan José, Gil-Oncina, Sara, Valdes-Abellan, Javier, Soler Llorens, Juan Luis, and Benavente, David

Abstract

The presence of radon in soil poses a significant health risk when it enters and concentrates indoors. The primary health problem associated with radon exposure is lung cancer, but it can also contribute to other respiratory issues. Estimating radon potential is a challenging task caused by the interaction of various environmental, geological, and variability factors. Although efforts are ongoing to improve radon potential assessment methodologies, there is a lack of software tools that estimate and model radon potential in different scenarios. The paper aims to develop a novel web-based software tool, RadonPotential, that predicts Geogenic Radon Potential by considering variations in climate and soil textures. The program runs using a constant radon concentration or estimates its concentration from the radium activity. RadonPotential calculates the transport of radon through a soil profile based on water content and soil texture. It also determines the dynamics of soil water content in different climates, incorporating long-term weather data under various climatic scenarios and local weather time series. The web-based format of the program increases its dissemination, usage, and manageability among a larger user base compared to an installable computer program. The program aims to provide a simplified and effective characterization of radon potential levels accessible to a wide range of scientists, technical experts and policymakers in developing strategies not only for radon measurement and mitigation buildings but also for developing more reliable large-scale radon potential maps.

Published

2024

8. Identification of high radon dwellings, risk of exposure, and geogenic potential in the mining area of the "TREPČA" complex.

Author

Gulan, Ljiljana, Forkapić, Sofija, Spasić, Dušica, Živković Radovanović, Jelena, Hansman, Jan, Lakatoš, Robert, and Samardžić, Selena

Subjects

*SINGLE family housing, *SOIL air, *RADON, *SOIL permeability

Abstract

This study was performed to investigate radon levels in dwellings in the mining area near the town of Kosovska Mitrovica. The Passive radon technique based on the charcoal canister test kit conducted in summer and autumn 2019 showed unexpected results. The reference level of 300 Bq/m3 for indoor radon concentration was exceeded in 15 of 26 dwellings. Preliminary measurements of gamma dose rate in some dwellings built from local stone showed values from 0.30 to 0.45 μSv/h, while 75% of measurements in dwellings with stone foundations had radon above the reference level. The highest radon concentration (22 500 ± 220 Bq/m3) was measured in the cellar of one family house. The RAD7 device (Durridge Company, Inc.) was used to measure radon concentrations in water and nearby soil of some dwellings. Indoor radon concentration fluctuated significantly over two days; over a one‐day time scale, radon varied from 2843 ± 217 Bq/m3 at midnight to 1449 ± 104 Bq/m3 in the morning at one site, and abruptly decreased from a maximum of 2146 ± 262 Bq/m3 in one day to a minimum of 21 Bq/m3 the next day at another site. The influence of geological substrate on radon exposure was discussed through the estimation of geogenic radon potential, which varies from low the high radon index despite to high permeability of soil. [ABSTRACT FROM AUTHOR]

Published

2022

9. Determining the Geogenic Radon Potential in Different Layouts and Numbers of Points

Author

Alexandru Lupulescu, Călin Baciu, Tiberius Dicu, Bety-Denissa Burghele, and Alexandra Laura Cucoș

Subjects

geogenic radon potential, soil permeability, natural radioactivity, radon, Meteorology. Climatology, QC851-999

Abstract

The geogenic radon potential is primarily controlled by the geological characteristics of the site, such as the rock type and structural elements, as well as the permeability of the soil. Depending on the scope of the survey, the geogenic radon potential can be mapped based on measurements conducted in the field at various resolutions. Detailed surveys are generally labour-intensive and time-consuming. Therefore, a balance should be reached between the desired level of precision and the required amount of effort, delivering the best results with the least number of resources. The international literature describes a variety of surveying techniques. This study was undertaken in a region of the central zone of the Poiana Rusca Mountains (Southern Carpathians, Romania) that contains several metamorphic, volcanic, and sedimentary rock types. The primary objective of the study is to compare alternative sampling point configurations, which vary in number and arrangement. The objective was to achieve the most accurate representation of the calculated geogenic radon potential while limiting the number of measurements and the time and effort associated with them. Radon activity concentration and soil permeability data were collected from 34 locations using seven alternative layouts of the sampling points. The proposed layouts were based on various configurations of fifteen, nine, five, and three sampling points. Locally, in some of the metamorphic units and in the regions containing sedimentary deposits with volcanic intercalations, the geogenic radon potential was found to be elevated. The results indicate that the three-measuring-point configuration is acceptable for general geogenic radon potential surveys.

Published

2023

10. Estimation of the Radon Risk Under Different European Climates and Soil Textures

Author

Sara Gil-Oncina, Javier Valdes-Abellan, Concepcion Pla, and David Benavente

Subjects

radon risk, Köppen climate classification, soil hydraulic properties, geogenic radon potential, radon soil transport, Public aspects of medicine, RA1-1270

Abstract

Radon is a radioactive gas produced from the natural radioactive decay of uranium and is found in almost all rocks and soils. In confined places (e.g., dwellings, workplaces, caves, and underground mines), radon may accumulate and become a substantial health risk since it is considered the second most important cause of lung cancer in many developed countries. Radon risk assessment commonly considers either field or estimate values of the radon concentration and the gas permeability of soils. However, radon risk assessment from single measurement surveys to radon potential largescale mapping is strongly sensitive to the soil texture variability and climate changes, and particularly, to the soil water content dynamic and its effect on soil gas permeability. In this paper, the gas permeability of soils, and thus, the estimation of radon risk, is studied considering the effect of three different climates following the Köppen classification and four soil textures on soil water content dynamics. This investigation considers the CLIGEN weather simulator to elaborate 100-year length climatic series; Rosseta 3 pedotransfer function to calculate soil hydraulics parameters, and the HYDRUS-1D software to model the dynamics of water content in the soil. Results reveal that climate strongly affects gas permeability of soils and they must be considered as an additional factor during the evaluation of radon exposure risk. The impact of climate and texture defines the soil water content dynamic. Coarse soils show smaller gas permeability variations and then radon risk, in this case, is less affected by the climate type. However, in clay soils, the effect of climate and the differences in soil water content derive in gas permeability variations between 100 and 1,000 times through an annual cycle. As a result, it may cross the boundary between two radon risk categories. Results deeply confirm that both climate and texture should be compulsory considered when calculating the radon exposure risk and in the definition of new strategies for the elaboration of more reliable geogenic radon potential largescale maps.

Published

2022

11. Air Quality Monitoring for Preventive Conservation of the Built Heritage Deteriorated by Salt Crystallization

Author

David Benavente, Concepción Pla, Sara Gil-Oncina, Maria Candela Ruiz, Idael Francisco Blanco-Quintero, Jose Antonio Huesca-Tortosa, Yolanda Spairani-Berrio, and Sergio Sanchez-Moral

Subjects

radon, salt weathering, geochemical modelling, wavelets, geogenic radon potential, Geology, QE1-996.5

Abstract

The Santo Domingo Diocesan School (Orihuela, SE Spain) is a singular case study that relates air quality monitoring and stone conservation. The monument suffers severe damage due to salt crystallization by rising damp, which is related to the indoor environment dynamics, high groundwater salt content, and microstructure, the building’s porous stone (biocalcarenite). Results revealed that 222Rn concentration in indoor air is low due to the building’s high ventilation rate, despite the medium-low geogenic radon potential in the area. Wavelets analysis showed that ventilation is caused by outdoor and indoor temperature variations and directly affects the 222Rn and CO2 dynamics inside the church. CO2, as well as relative humidity (RH), presented periodicities with intermediate frequencies (5–8 days) related to visits. These RH and temperature (T) variations intensified the salt damage by increasing the frequency of dissolution-crystallization cycles. The mineralogical characterization and geochemical calculations concluded that chlorides (halite and sylvite), sulfates (thenardite, epsomite, hexahydrite and aphthitalite) and nitrates (niter) present from dissolution forms to whiskers and hopper-type morphologies. This indicates high saturation values and, therefore, higher crystallization pressure values within the porous media of the biocalcarenite. On the contrary, the near-equilibrium crystal shape and incongruent precipitation reaction for humberstonite suggest a lower alteration for this salt on the building stone.

Published

2022

12. Study of the possibility of using radon potential maps for identification of areas with high indoor radon concentration.

Author

Bulko, Martin, Holý, Karol, Brandýsová, Alžbeta, Müllerová, Monika, and Masarik, Jozef

Subjects

*RADON, *POSSIBILITY, *CITIES & towns

Abstract

In this study, five different methods for determining the geogenic radon potential are compared in the Mochovce region, Slovakia. Based on these methods, maps of radon potential were made and localities with suspected elevated indoor radon levels were identified. Subsequently, indoor radon concentrations measurements were performed there. Based on the measurements in six municipalities, an approximately linear relationship was found between the values of geogenic radon potential and indoor radon concentrations. These results confirm the usability of radon potential maps as valuable tools for characterizing radon-prone areas. [ABSTRACT FROM AUTHOR]

Published

2021

13. A new perspective in radon risk assessment: Mapping the geological hazard as a first step to define the collective radon risk exposure.

Author

Benà, Eleonora, Ciotoli, Giancarlo, Petermann, Eric, Bossew, Peter, Ruggiero, Livio, Verdi, Luca, Huber, Paul, Mori, Federico, Mazzoli, Claudio, and Sassi, Raffaele

Published

2024

14. Assessment of natural radioactivity and radon release potential of silurian black shales.

Author

DaPelo, Stefania, Aghdam, Mirsina Mousavi, Dentoni, Valentina, Loi, Alfredo, Randaccio, Paolo, and Crowley, Quentin

Subjects

*NATURAL radioactivity, *BLACK shales, *RADON, *ROCK texture, *RADIOISOTOPES, *GAMMA ray spectrometry, *REAL estate development, *SHALE

Abstract

Many countries are developing a radon action plan to provide decision-makers with a reliable tool for reducing the harmful effects of radon exposure in dwellings and among the general public and, accordingly, to implement land development strategies. Mapping the geogenic radon release in different geological environments could assist in delineating areas that require priority monitoring and regulation, as well as applying radon reduction techniques in newly constructed buildings. In this paper, the activity concentration of 238U, 226Ra, 232Th and 40K and the exhalation rate of 222Rn have been estimated for the Silurian black shales of Villasalto, a district in the south-eastern Sardinia (Italy). The radioactivity of 226Ra, 232Th and 40K radionuclides was found relatively high (256.32 ± 87.00 Bq.kg−1), low (44.16 ± 9.47 Bq.kg−1) and moderate to high (856.28 ± 392.41 Bq.kg−1) respectively. The radon emanation coefficient (E) and the radon production rate (P Rn) have been calculated based on the analysis of the radon growth model inside a sealed chamber. E was found to correlate well with the activity concentration of 226Ra, as well as with the grain size of the soil/rock samples under investigation. P Rn was relatively high, ranging from 212.54 to 524.27 Bq.m−3.h−1. Furthermore, the mean value of the main radiation hazard indexes (i.e., the radium equivalent activity , the outdoor gamma-ray dose rate and the annual e ff ective dose) were found to be 299.07 ± 138.62 Bq.kg−1, 169.97 ± 75.58 nGy h−1 and 0.21 ± 0.09 mSv.y−1 respectively. • High levels of uranium and radon were found in Silurian Black Shales. • Correlation between radon coefficient and rock texture discovered. • Study provides insights into geological factors contributing to natural radioactivity. • Implications for radioprotection measures and identifying Radon Priority Areas investigated. • Continued research in this area is crucial for understanding potential health risks. [ABSTRACT FROM AUTHOR]

Published

2024

15. Assessment of radon risk areas in the Eastern Canary Islands using soil radon gas concentration and gas permeability of soils.

Author

Alonso, H., Rubiano, J.G., Guerra, J.G., Arnedo, M.A., Tejera, A., and Martel, P.

Abstract

Abstract The Basic Safety Standard (BSS) Directive 2013/59/EURATOM of the European Union (EU) has stated the need for member states to establish national action plans to mitigate their general population's long-term risks of exposure to radon gas. Maps of radon-prone areas provide a useful tool for the development of such plans. This paper presents the maps of radon-prone areas in the Eastern Canary Islands (Gran Canaria, Fuerteventura and Lanzarote) obtained from assessment of Geogenic Radon Potential (GRP) distribution in the territory. GRP constitutes a magnitude that is contingent on both radon activity concentration and gas permeability of soils. An extensive campaign covering all geological formations of the Eastern Canary Islands was undertaken to locally sample these parameters. Geostatistical analysis of the spatial distribution of radon concentration in soils, permeability and GRP was performed on each of the islands, and the relationship between these magnitudes and the characteristic geological formations of the volcanic islands was investigated. Areas dominated by basic volcanic and plutonic rocks (originated by both recent and ancient volcanism) exhibit relatively low levels of radon in soils, and with the exception of specific cases of very high permeability, these areas are not classified as prone to radon risk according to international criteria. Areas in which intermediate or acidic volcanic and plutonic rocks predominate are characterised by greater radon activity concentration in soils, rendering them radon-prone. Given these results, Lanzarote is classified as an island with low radon risk all over its surface; Fuerteventura presents low-medium risk; and Gran Canaria contains extensive areas in the centre and north where the risk is medium or high. This classification is consistent with the risk maps obtained by National and European agencies from indoor radon measurements conducted on these islands. Graphical abstract Unlabelled Image Highlights • EU Member states have to establish action plans to mitigate radon exposure risks. • A study of Soil radon gas concentration and gas permeability of soils were performed. • Geogenic Radon Potential (GRP) distribution in the territory have been assessed. • Maps of radon prone areas in the Eastern Canary Islands are displayed based on GRP. • The subsequent zonal classification agrees with those provided by the authorities. [ABSTRACT FROM AUTHOR]

Published

2019

16. Mapping the geogenic radon potential and radon risk by using Empirical Bayesian Kriging regression: A case study from a volcanic area of central Italy.

Author

Giustini, Francesca, Ciotoli, Giancarlo, Rinaldini, Alessio, Ruggiero, Livio, and Voltaggio, Mario

Abstract

Abstract A detailed geochemical study on radon related to local geology was carried out in the municipality of Celleno, a little settlement located in the eastern border of the Quaternary Vulsini volcanic district (central Italy). This study included soil-gas and terrestrial gamma dose rate survey, laboratory analyses of natural radionuclides (238U, 226Ra, 232Th, 40K) activity in rocks and soil samples, and indoor radon measurements carried out in selected private and public dwellings. Soil-gas radon and carbon dioxide concentrations range from 6 to 253 kBq/m3 and from 0.3 to11% v/v, respectively. Samples collected from outcropping volcanic and sedimentary rocks highlight: significant concentrations of 238U, 226Ra and 40K for lavas (151, 150 and 1587 Bq/kg, respectively), low concentrations for tuffs (126, 123 and 987 Bq/kg, respectively), and relatively low for sedimentary rocks (108, 109 and 662 Bq/kg, respectively). Terrestrial gamma dose rate values range between 0.130 and 0.417 μSv/h, being in good accordance with the different bedrock types. Indoor radon activity ranges from 162 to 1044 Bq/m3; the calculated values of the annual effective dose varied from 4.08 and 26.31 mSv/y. Empirical Bayesian Kriging Regression (EBKR) was used to develop the Geogenic Radon Potential (GRP) map. EBKR provided accurate predictions of data on a local scale developing a spatial regression model in which soil-gas radon concentrations were considered as the response variable; several proxy variables, derived from geological, topographic and geochemical data, were used as predictors. Risk prediction map for indoor radon was tentatively produced using the Gaussian Geostatistical Simulation and a soil-indoor transfer factor was defined for a 'standard' dwelling (i.e., a dwelling with well-defined construction properties). This approach could be successfully used in the case of homogeneous building characteristics and territory with uniform geological characteristics. Graphical abstract Unlabelled Image Highlights • A detailed geochemical study on radon was carried out in a volcanic area of central Italy. • Geogenic Radon Potential map was developed using Empirical Bayesian Kriging Regression. • A soil-indoor transfer factor was defined for a 'standard' dwelling. • Indoor Rn partly depends on housing characteristics (e.g., tuff used as building material) [ABSTRACT FROM AUTHOR]

Published

2019

17. Applying machine learning to model radon using topsoil geochemistry.

Author

Banríon, M., Cobelli, M., and Crowley, Q.G.

Subjects

*RADON, *MACHINE learning, *GEOCHEMISTRY, *KRIGING, *TOPSOIL, *ANALYTICAL geochemistry

Abstract

Radon is classified as a Class 1 carcinogen, being the leading cause of lung cancer in non-smokers. Understanding the prominent sources of radon helps to mitigate against the adverse effects of radon exposure. Considering soil-gas radon is the main contributor to indoor radon, it is possible that soil geochemistry can be used as a proxy for the soil radon emanation potential or geogenic radon classes for a particular location. This paper investigates the relationship between soil geochemistry and geogenic radon. A large area of 17,983 km2 from the West, Midlands and East of Ireland was selected to represent a range of geology types and radon categories. A rigorous assessment is presented to investigate the relationship of geogenic radon and topsoil geochemistry; using univariate processes (i.e. r2, Pearson r and heatmaps) and multivariate techniques (i.e. principle component analysis (PCA) and machine learning (ML) algorithms including Gaussian process regression, logistic regression and random forest). Here, PCA and ML techniques were used to test the utility of soil geochemistry to predict geogenic radon classes. Gaussian Process Regression yielded the highest accuracy (74%) and f1-score (0.74) of all models. The feature importance (i.e. highest ranking elements for predicting geogenic radon class) from the ML models outputs elements including [Y, Tl, Mn, Cr, Co, Be, Sc and Rb]. The PCA biplot demonstrates that these elements cluster in conjunction with higher geogenic radon categories. Multivariate data analysis reveals that certain elements important for predicting higher geogenic radon classes, also covary together within topsoil samples; here these are termed "radon-prone elements". Spatial covariance of radon-prone elements permits soil geochemistry to be used as a tool for understanding the distribution of geogenic radon. The methodology presented in this paper provides a comprehensive geo-statistical approach to investigate the relation between topsoil geochemistry and geogenic radon. This approach could be applied as a diagnostic tool to assist radon mitigation measures, hence adding value to legacy soil geochemistry datasets. • ML and PCA results indicate radon prone elements. • Gaussian process regression achieves the highest accuracy (74%) for classifying geogenic radon class. • Relationship between soil geochemistry and geogenic radon investigated. • Topsoil geochemical analysis significantly correlates to geogenic radon class. • Spatial covariance of elements (including Y, Tl, Mn, Cr, Co, Al, Rb) and elevated geogenic radon. [ABSTRACT FROM AUTHOR]

Published

2023

18. Radon Concentration in Groundwater and Soil Gas Radon in Agbabu Bituminous Deposit Area: Mapping, GR Potential and Health Risks Assessments

Author

Faweya, E. B., Adewumi, T., Ajiboye, Y., Akande, H. T., and Rasheed, H. A.

Published

2021

19. Estimation of the Radon Risk Under Different European Climates and Soil Textures

Author

Universidad de Alicante. Departamento de Ciencias de la Tierra y del Medio Ambiente, Universidad de Alicante. Departamento de Ingeniería Civil, Gil-Oncina, Sara, Valdes-Abellan, Javier, Pla, Concepción, Benavente, David, Universidad de Alicante. Departamento de Ciencias de la Tierra y del Medio Ambiente, Universidad de Alicante. Departamento de Ingeniería Civil, Gil-Oncina, Sara, Valdes-Abellan, Javier, Pla, Concepción, and Benavente, David

Abstract

Radon is a radioactive gas produced from the natural radioactive decay of uranium and is found in almost all rocks and soils. In confined places (e.g., dwellings, workplaces, caves, and underground mines), radon may accumulate and become a substantial health risk since it is considered the second most important cause of lung cancer in many developed countries. Radon risk assessment commonly considers either field or estimate values of the radon concentration and the gas permeability of soils. However, radon risk assessment from single measurement surveys to radon potential largescale mapping is strongly sensitive to the soil texture variability and climate changes, and particularly, to the soil water content dynamic and its effect on soil gas permeability. In this paper, the gas permeability of soils, and thus, the estimation of radon risk, is studied considering the effect of three different climates following the Köppen classification and four soil textures on soil water content dynamics. This investigation considers the CLIGEN weather simulator to elaborate 100-year length climatic series; Rosseta 3 pedotransfer function to calculate soil hydraulics parameters, and the HYDRUS-1D software to model the dynamics of water content in the soil. Results reveal that climate strongly affects gas permeability of soils and they must be considered as an additional factor during the evaluation of radon exposure risk. The impact of climate and texture defines the soil water content dynamic. Coarse soils show smaller gas permeability variations and then radon risk, in this case, is less affected by the climate type. However, in clay soils, the effect of climate and the differences in soil water content derive in gas permeability variations between 100 and 1,000 times through an annual cycle. As a result, it may cross the boundary between two radon risk categories. Results deeply confirm that both climate and texture should be compulsory considered when calculating the radon exp

Published

2022

20. Air Quality Monitoring for Preventive Conservation of the Built Heritage Deteriorated by Salt Crystallization

Author

Universidad de Alicante. Departamento de Ciencias de la Tierra y del Medio Ambiente, Universidad de Alicante. Departamento de Ingeniería Civil, Universidad de Alicante. Departamento de Construcciones Arquitectónicas, Benavente, David, Pla, Concepción, Gil-Oncina, Sara, Ruiz, Maria Candela, Blanco-Quintero, Idael Francisco, Huesca Tortosa, José Antonio, Spairani-Berrio, Yolanda, Sánchez Moral, Sergio, Universidad de Alicante. Departamento de Ciencias de la Tierra y del Medio Ambiente, Universidad de Alicante. Departamento de Ingeniería Civil, Universidad de Alicante. Departamento de Construcciones Arquitectónicas, Benavente, David, Pla, Concepción, Gil-Oncina, Sara, Ruiz, Maria Candela, Blanco-Quintero, Idael Francisco, Huesca Tortosa, José Antonio, Spairani-Berrio, Yolanda, and Sánchez Moral, Sergio

Abstract

The Santo Domingo Diocesan School (Orihuela, SE Spain) is a singular case study that relates air quality monitoring and stone conservation. The monument suffers severe damage due to salt crystallization by rising damp, which is related to the indoor environment dynamics, high groundwater salt content, and microstructure, the building’s porous stone (biocalcarenite). Results revealed that 222Rn concentration in indoor air is low due to the building’s high ventilation rate, despite the medium-low geogenic radon potential in the area. Wavelets analysis showed that ventilation is caused by outdoor and indoor temperature variations and directly affects the 222Rn and CO2 dynamics inside the church. CO2, as well as relative humidity (RH), presented periodicities with intermediate frequencies (5–8 days) related to visits. These RH and temperature (T) variations intensified the salt damage by increasing the frequency of dissolution-crystallization cycles. The mineralogical characterization and geochemical calculations concluded that chlorides (halite and sylvite), sulfates (thenardite, epsomite, hexahydrite and aphthitalite) and nitrates (niter) present from dissolution forms to whiskers and hopper-type morphologies. This indicates high saturation values and, therefore, higher crystallization pressure values within the porous media of the biocalcarenite. On the contrary, the near-equilibrium crystal shape and incongruent precipitation reaction for humberstonite suggest a lower alteration for this salt on the building stone.

Published

2022

21. Air Quality Monitoring for Preventive Conservation of the Built Heritage Deteriorated by Salt Crystallization

Author

Ministerio de Ciencia, Innovación y Universidades (España), Generalitat Valenciana, Benavente, David, Pla, Concepción, Gil-Oncina, Sara, Candela Ruiz, María, Blanco-Quintero, Idael Francisco, Huesca-Tortosa, José Antonio, Spairani-Berrio, Yolanda, Sánchez-Moral, Sergio, Ministerio de Ciencia, Innovación y Universidades (España), Generalitat Valenciana, Benavente, David, Pla, Concepción, Gil-Oncina, Sara, Candela Ruiz, María, Blanco-Quintero, Idael Francisco, Huesca-Tortosa, José Antonio, Spairani-Berrio, Yolanda, and Sánchez-Moral, Sergio

Abstract

The Santo Domingo Diocesan School (Orihuela, SE Spain) is a singular case study that relates air quality monitoring and stone conservation. The monument suffers severe damage due to salt crystallization by rising damp, which is related to the indoor environment dynamics, high groundwater salt content, and microstructure, the building’s porous stone (biocalcarenite). Results revealed that 222Rn concentration in indoor air is low due to the building’s high ventilation rate, despite the medium-low geogenic radon potential in the area. Wavelets analysis showed that ventilation is caused by outdoor and indoor temperature variations and directly affects the 222Rn and CO2 dynamics inside the church. CO2, as well as relative humidity (RH), presented periodicities with intermediate frequencies (5–8 days) related to visits. These RH and temperature (T) variations intensified the salt damage by increasing the frequency of dissolution-crystallization cycles. The mineralogical characterization and geochemical calculations concluded that chlorides (halite and sylvite), sulfates (thenardite, epsomite, hexahydrite and aphthitalite) and nitrates (niter) present from dissolution forms to whiskers and hopper-type morphologies. This indicates high saturation values and, therefore, higher crystallization pressure values within the porous media of the biocalcarenite. On the contrary, the near-equilibrium crystal shape and incongruent precipitation reaction for humberstonite suggest a lower alteration for this salt on the building stone.

Published

2022

22. Radon survey in Chelyabinsk Oblast, Russia, in 2008–2011. Analysis of spatial variability of indoor radon concentration

Author

A. M. Marennyy, D. V. Kononenko, and A. E. Trufanova

Subjects

concentration, Percentile, data analysis, R895-920, chemistry.chemical_element, Radon, 010501 environmental sciences, 01 natural sciences, 030218 nuclear medicine & medical imaging, radon survey, Medical physics. Medical radiology. Nuclear medicine, 03 medical and health sciences, 0302 clinical medicine, ecological and radiogeochemical zone, Urban district, Radiology, Nuclear Medicine and imaging, QC794.95-798, 0105 earth and related environmental sciences, Radioactivity and radioactive substances, Median, Significant difference, lognormal distribution, chelyabinsk oblast, radon, ssntd, geogenic radon potential, chemistry, Log-normal distribution, Environmental science, Spatial variability, Physical geography, Arithmetic mean

Abstract

An extensive radon survey was conducted in 2008-2011 in the framework of the Federal target program on the territory of 29 districts of Chelyabinsk Oblast. SSNTDs were used to measure indoor radon concentrations in public buildings, dwellings and industrial buildings. The results are stored in the database “Radon” owned by Research and Technical Center of Radiation-Chemical Safety and Hygiene of Federal Medical-Biological Agency. The paper presents the results of the analysis of spatial variability of indoor radon concentration and the relationship of this value with a set of geological predictors of radon potential of the territory integrated into a map of ecological and radiogeochemical zones. The results show that in all districts and the whole Chelyabinsk Oblast radon concentrations conform to a lognormal distribution, but in ten districts log-logistic distribution fits the data slightly better. Nevertheless, relative difference between the median values of indoor radon concentration calculated from the two fitted distributions yields zero. The results show that dose assessment based on the arithmetic means could lead to an overestimation of the doses from radon in 1.4 times on average compared to that based on the medians. The median value does not exceed 400 Bq/m3 in any of the surveyed territories and the 95th percentile lies between 96 and 1274 Bq/m3. The fraction of indoor radon concentrations above 400 Bq/m3 expected from the fitted distribution lies between less than 0.1 and 26.8%. The highest values of this fraction were obtained for the Sosnovsky, Kaslinsky, Bredinsky districts and the Miassky urban district (except for the city of Miass). A map of ecological and radiogeochemical zones in Chelyabinsk Oblast was released in 1993-1995 and it was based on a set of geological predictors of radon potential of the territory. We analyzed the relationship of these zones with the results of the radon survey. One-way ANOVA on ranks with the Bonferroni correction showed that there is no statistically significant difference at the 95% confidence level amongst the medians of indoor radon concentration on basement, ground and first floors in settlements, which are located on the territory of three of four of these zones and outside of the territory of all zones. In the fourth zone the median was even two times lower than outside of the zones. These results lead to the conclusion that the possibility of using this map as a map of radon-prone areas is very doubtful. Each datapoint stored in the “Radon” database has a number of additional properties, which allows analyzing other types of indoor radon concentration variability such as seasonal or floor-to-floor. It is expected that later this dataset could be used for estimating regional seasonal correction factors.

Published

2020

23. Correlation between radon in water, radon in soil gas and indoor radon based on the extensive measurements in Croatia

Author

Poje Sovilj, Marina, Miklavčić Igor, Šmit, Goran, Stanić, Denis, Radolić, Vanja, and Ristić, Goran S.

Subjects

radon concentration in water, indoor radon concentartions, geogenic radon potential, Spearman correlation coefficient

Abstract

Radon is known as the main source of radiation for the general public. Radon is a part of the uranium (238U) decay chain and is formed by radioactive decay of its parent radium nucleus (226Ra) inside various geological structures (both rock and soil minerals) in which radium is naturally present in various concentrations. Radon enters water most often by dissolving in groundwater that surrounds geological structures. And to a much lesser extent, radon can enter water by dissolving from the air. Clean and safe tap water for human consumption is one of the important goals of the EU according to the Horizon Europe – the next EU research and innovation programme 2021 – 2027. Results of extensive measurements of radon in water samples collected from private wells, natural springs and public water supply in Croatia are presented and annual effective doses are estimated. Since 2011 water samples were gathered during targeted indoor radon surveys (schools, kindergartens and homes) in 10 counties (out of 21) in Croatia. Radon activity concentrations in water were determined by two different methods: by using the emanometry method (AlphaGUARD instrument with additional AquaKIT module) and the liquid scintillation method (LSC TriCarb). A total of almost 1000 water samples gathered in the field gave the arithmetic mean of 5 Bq/l (with the measured minimum value below detection limit - around 1 Bq/l ; on the other hand, maximum measured value was 154 Bq/l). These concentrations result in average ingestion doses around 30 μSv for adults and 50 μSv for children. Correlation between radon concentration in water samples, indoor radon concentrations (measured by SSNTDs in a yearlong measurements) and calculated geogenic radon potential (based on the radon in soil gas measured by radon detector RM-2 and soil permeability measured by Radon-JOK instrument) in selected counties are examined. All of these measurements were performed in the investigated dwellings or in its immediate vicinity. The results of these correlations can serve as a starting point for more detailed investigations in defining radon priority areas in Croatia, in the future. By doing a statistical analysis of the data gathered in each county the Spearman correlation coefficients (nonparametric version of the Pearson correlation coefficient) are calculated in order to measure the degree of association between two variables based on their ranks. We wanted to analyse correlations between these measured variables: indoor radon, radon in soil gas, geogenic radon potential (GRP) and radon in water. In all of the cases a positive correlation is found with strong (rs = 0.6 - 0.8) or moderate (rs = 0.4 - 0.6) relationship between measured variables.

Published

2022

24. Radon Hazard in Central Italy: Comparison among Areas with Different Geogenic Radon Potential

Author

Francesca Giustini, Livio Ruggiero, Alessandra Sciarra, Stan Eugene Beaubien, Stefano Graziani, Gianfranco Galli, Luca Pizzino, Maria Chiara Tartarello, Carlo Lucchetti, Pietro Sirianni, Paola Tuccimei, Mario Voltaggio, Sabina Bigi, Giancarlo Ciotoli, Giustini, F., Ruggiero, L., Sciarra, A., Beaubien, S. E., Graziani, S., Galli, G., Pizzino, L., Tartarello, M. C., Lucchetti, C., Sirianni, P., Tuccimei, P., Voltaggio, M., Bigi, S., and Ciotoli, G.

Subjects

Health, Toxicology and Mutagenesis, Public Health, Environmental and Occupational Health, risk assessment, geogenic radon potential, soil gas and indoor radon, Article, Geogenic radon potential, Air Pollutants, Radioactive, Gamma Rays, Radiation Monitoring, Radon, Air Pollution, Indoor, Medicine, Soil Pollutants, Radioactive, Risk assessment, Soil gas and indoor radon

Abstract

Radon (222Rn) is a natural radioactive gas formed in rocks and soil by the decay of its parent nuclide (238-Uranium). The rate at which radon migrates to the surface, be it along faults or directly emanated from shallow soil, represents the Geogenic Radon Potential (GRP) of an area. Considering that the GRP is often linked to indoor radon risk levels, we have conducted multi-disciplinary research to: (i) define local GRPs and investigate their relationship with associated indoor Rn levels; (ii) evaluate inhaled radiation dosages and the associated risk to the inhabitants; and (iii) define radon priority areas (RPAs) as required by the Directive 2013/59/Euratom. In the framework of the EU-funded LIFE-Respire project, a large amount of data (radionuclide content, soil gas samples, terrestrial gamma, indoor radon) was collected from three municipalities located in different volcanic districts of the Lazio region (central Italy) that are characterised by low to high GRP. Results highlight the positive correlation between the radionuclide content of the outcropping rocks, the soil Rn concentrations and the presence of high indoor Rn values in areas with medium to high GRP. Data confirm that the Cimini–Vicani area has inhalation dosages that are higher than the reference value of 10 mSv/y.

Published

2022

25. The assessment of local geological factors for the construction of a Geogenic Radon Potential map using regression kriging. A case study from the Euganean Hills volcanic district (Italy)

Author

Jacopo Nava, Laura Tositti, Antonio Galgaro, Alessandra Sciarra, Claudio Mazzoli, Giorgia Cinelli, Domiziano Mostacci, Erika Brattich, Paolo Mozzi, Pietro Morozzi, Chiara Coletti, Matteo Massironi, Livio Ruggiero, Giancarlo Ciotoli, Eleonora Benà, Raffaele Sassi, and Chiara Coletti, Giancarlo Ciotoli, Elena Benà, Erika Brattich, Giorgia Cinelli, Antonio Galgaro, Matteo Massironi, Claudio Mazzoli, Domiziano Mostacci, Pietro Morozzi, Paolo Mozzi, Jacopo Nava, Livio Ruggero, Alessandra Sciarra, Laura Tositti, Raffaele Sassi

Subjects

Environmental Engineering, Euganean Hills, chemistry.chemical_element, Radon, Soil science, Settore GEO/09 - Georisorse Miner.Appl.Mineral.-Petrogr.per l'amb.e i Beni Cul, Fault (geology), Geogenic Radon Potential, Geostatistics, Natural radioactivity, Regression kriging, Kriging, Radiation Monitoring, Environmental Chemistry, Soil Pollutants, Radioactive, Digital elevation model, Waste Management and Disposal, Subsoil, geography, Spatial Analysis, geography.geographical_feature_category, Soil gas, Bedrock, Bayes Theorem, Euganean Hills, Geogenic Radon Potential, Geostatistics, Natural radioactivity, Radon, Regression kriging, Pollution, chemistry, Air Pollutants, Radioactive, Radon, natural radioactivity, Geogenic Radon Potential, Regression kriging, Geostatistics, Euganean Hills, Environmental science, Scale (map)

Abstract

The assessment of potential radon-hazardous environments is nowadays a critical issue in planning, monitoring, and developing appropriate mitigation strategies. Although some geological structures (e.g., fault systems) and other geological factors (e.g., radionuclide content, soil organic or rock weathering) can locally affect the radon occurrence, at the basis of a good implementation of radon-safe systems, optimized modelling at territorial scale is required. The use of spatial regression models, adequately combining different types of predictors, represents an invaluable tool to identify the relationships between radon and its controlling factors as well as to construct Geogenic Radon Potential (GRP) maps of an area. In this work, two GRP maps were developed based on field measurements of soil gas radon and thoron concentrations and gamma spectrometry of soil and rock samples of the Euganean Hills (northern Italy) district. A predictive model of radon concentration in soil gas was reconstructed taking into account the relationships among the soil gas radon and seven predictors: terrestrial gamma dose radiation (TGDR), thoron (220Rn), fault density (FD), soil permeability (PERM), digital terrain model (SLOPE), moisture index (TMI), heat load index (HLI). These predictors allowed to elaborate local spatial models by using the Empirical Bayesian Regression Kriging (EBRK) in order to find the best combination and define the GRP of the Euganean Hills area. A second GRP map based on the Neznal approach (GRPNEZ) has been modelled using the TGDR and 220Rn, as predictors of radon concentration, and FD as predictor of soil permeability. Then, the two GRP maps have been compared. Results highlight that the radon potential is mainly driven by the bedrock type but the presence of fault systems and topographic features play a key role in radon migration in the subsoil and its exhalation at the soil/atmosphere boundary.

Published

2022

26. Detailed Geogenic Radon Potential Mapping Using Geospatial Analysis of Multiple Geo-Variables—A Case Study from a High-Risk Area in SE Ireland

Author

Quentin Crowley, Mirsina Mousavi Aghdam, Stefania Da Pelo, and VALENTINA DENTONI

Subjects

Soil, Radon, Air Pollutants, Radioactive, Radiation Monitoring, Air Pollution, Indoor, Health, Toxicology and Mutagenesis, Public Health, Environmental and Occupational Health, geogenic radon potential, geostatistical analysis, radon-related variables, soil gas radon, airborne radiometric, Humans, Soil Pollutants, Radioactive, Bayes Theorem

Abstract

A detailed investigation of geogenic radon potential (GRP) was carried out near Graiguenamanagh town (County Kilkenny, Ireland) by performing a spatial regression analysis on radon-related variables to evaluate the exposure of people to natural radiation (i.e., radon, thoron and gamma radiation). The study area includes an offshoot of the Caledonian Leinster Granite, which is locally intruded into Ordovician metasediments. To model radon release potential at different points, an ordinary least squared (OLS) regression model was developed in which soil gas radon (SGR) concentrations were considered as the response value. Proxy variables such as radionuclide concentrations obtained from airborne radiometric surveys, soil gas permeability, distance from major faults and a digital terrain model were used as the input predictors. ArcGIS and QGIS software together with XLSTAT statistical software were used to visualise, analyse and validate the data and models. The proposed GRP models were validated through diagnostic tests. Empirical Bayesian kriging (EBK) was used to produce the map of the spatial distribution of predicted GRP values and to estimate the prediction uncertainty. The methodology described here can be extended for larger areas and the models could be utilised to estimate the GRPs of other areas where radon-related proxy values are available.

Published

2022

27. Mapping the Geogenic Radon Hazard Index of Italy

Author

Francesca Giustini, Monia Procesi, MariaGrazia Finoia, Raffaele Sassi, Claudio Mazzoli, and Giancarlo Ciotoli

Subjects

geogenic radon hazard map, machine learning, Italy, radon, geogenic radon, multicriteria decision analysis, geogenic radon potential

Abstract

Radon generation and migration from the soil toward the surface are natural processes that can lead to radon entry in buildings, thus constituting a health risk. The analysis and the modelling of these processes can be thought of as the contribution of different proxies representing the geological radon source (GRS) (e.g., geology, soil properties, radionuclide content), and the pathways (e.g., faults, karst) that favour the geological radon migration (GRM) in the subsoil. The aggregation of these quantities can be used to construct a geogenic radon hazard index (GRHI) map that can be understood as a measure of the susceptibility of an area to increased indoor radon concentration for geogenic reasons (Radon Priority Areas, RPA).A number of direct and indirect models have been developed in order to create GRHI maps of a certain region by using both deterministic and probabilistic models. Here, we propose a bottom-up procedure through the integration of different factors (predictors and/or proxies) and by weighs their importance. In particular, we first propose to construct a GRHI map of the whole Italian territory using a GIS-based (spatial) multicriteria decision analysis (SMCDA). SMCDA uses the Analytical HierarchyProcess (AHP) to assess the importance of the factors and to derive their relative weights and, consequently, it determines the overall final scores.Lithologies of the National Geological Map of Italy (1:1000000) were reclassified in few homogeneous classes and ranked according to the associated mean content of uranium, thorium and potassium available from GEMAS (http://gemas.geolba.ac.at/) and FOREGS (http://weppi.gtk.fi/publ/foregsatlas/index.php) database by using a multivariate statistical approach. In this way the intermediate map of the GRS was obtained. SMCDA was then applied by using the GRS map and the maps of other factors, such as the fine fraction of the soil (LUCAS top-soil database, https://esdac.jrc.ec.europa.eu/projects/lucas), the fault density map (Italian national/regional datasets), the map of the karst areas (https://www.whymap.org/whymap/EN/Maps_Data/Wokam/wokam_node_en.html) and the map of the heat flow of Italy. All these factors were standardised by using fuzzy classification to transform input data to a 0/1 scale. The standardised factors are weighted by using AHP and then summed to obtain the final GRHI map. All maps are constructed at the same grid resolution of the European Atlas of Natural Radiation (10x10km) (https://remon.jrc.ec.europa.eu/About/Atlas-of-Natural-Radiation) published by the Joint Research Centre (JRC) of the European Commission.

Published

2021

28. The Empirical Bayesian Regression Kriging (EBRK) to map the Geogenic Radon Potential (GRP). A case of study from the Euganean Hills (Italy)

Author

Chiara Coletti, Giancarlo Ciotoli, Eleonora Benà, Erika Brattich, Giorgia Cinelli, Antonio Galgaro, Matteo Massironi, Claudio Mazzoli, Domiziano Mostacci, Paolo Mozzi, Livio Ruggiero, Alessandra Sciarra, Laura Tositti, and Raffaele Sassi

Subjects

Colli Euganei, Geogenic radon potential, Italy, Empirical Bayesian Regression Kriging

Abstract

In the volcanic area of the Euganean Hills district (100 km2), the indoor radon often exceeds the threshold level of 300 Bq/m3 stipulated by the Council Directive 2013/59/Euratom, thus suggesting the need to investigate the possible link between observed radon concentrations and the local geology (Trotti et al., 1998,1999; Strati et al., 2014). More recently, statistical and geostatistical analysis on rock samples identified high U, Th and K concentrations associated with areas characterised by trachyte and rhyolite lithologies (Tositti et al., 2017). With this contribution, we completed our investigation on the natural radioactivity in the Euganean Hills district extending the rocks dataset, performing on-site soil gas survey, and considering other important factors which can locally increase the radon occurrence, such as hydrothermal alterations, types of soils (e.g., geochemistry or presence of organic matters), and faults. Furthermore, we elaborated a Geogenic Radon Potential map to assess the local spatial relationships between the measured soil gas radon concentrations and seven proxy-variables: fault density (FD), total gamma radiation dose (TGDR), 220Rn (Tn), digital terrain mode (SLOPE), moisture index (MI), heat load index (HLI) and soil permeability (PERM). Empirical Bayesian Regression Kriging (EBRK) was used to develop the most accurate hazard map of the considered area, thus, providing the local administration an up-to-date decisional tool for the land use planning. For the high radon emission measured, the high density of dwelling, and its geomorphological features, the Euganean Hills district represented a very meaningful case of study. Trotti, F., Tanferi, A., Lanciai, M., Mozzo, P., Panepinto, V., Poli, S., Predicatori, F., Righetti, F., Tacconi, A., Zorzine, R., 1998. Mapping of areas with elevated indoor radon levels in Veneto. Radiat. Prot. Dosim. 78 (1), 11–14.Trotti, F., Tanferi, A., Bissolo, F., Fustegato, R., Lanciai, M., Mozzo, P., Predicatori, F., Querini, P., Righetti, F., Tacconi, A., 1999. A Survey to Map Areas with Elevated Indoor Radon Levels in Veneto, Radon in the Living Environment, 19-23 April 1999, Athens, Greece, 859–868.Strati V., Baldoncini M., Bezzon G.P, Broggini C., Buso G.P., Caciolli A., Callegari I., Carmignani L, Colonna T, Fiorentini G., Guastaldi E., Kaçeli Xhixhaf M., Mantovani F, Menegazzo R., Moub L., Rossi Alvarez C., Xhixha G., Zanon A., 2014. Total natural radioactivity, Veneto (Italy). Journal of Maps, Vol. 11, Issue 4, 545–551. http://doi.org/10.1080/17445647.2014.923348.Tositti L., Cinelli G., Brattich E., Galgaro A., Mostacci D., Mazzoli C., Massironi M., Sassi R., 2017. Assessment of lithogenic radioactivity in the Euganean Hills magmatic district (NE Italy). J. Environ. Radioact. 166, 259–269. https://doi.org/10.1016/j.jenvrad.2016.07.011

Published

2021

29. Determination of radon prone areas by optimized binary classification.

Author

Bossew, P.

Subjects

*CHEMICAL ecology, *RADON, *INDOOR air quality, *ESTIMATION theory, *HEALTH, *SMOKING, *LUNG cancer, *STATISTICS

Abstract

Abstract: Geogenic radon prone areas are regions in which for natural reasons elevated indoor radon concentrations must be expected. Their identification is part of radon mitigation policies in many countries, as radon is acknowledged a major indoor air pollutant, being the second cause of lung cancer after smoking. Defining and estimating radon prone areas is therefore of high practical interest. In this paper a method is presented which uses the geogenic radon potential as predictor and thresholds of indoor radon concentration for defining radon prone areas, from which thresholds for the geogenic radon potential are deduced which decide whether a location is flagged radon prone or not, in the absence of actual indoor observations. The overall results are different maps of radon prone areas, derived from the geogenic radon map, and depending (1) on the criterion which defines what a radon prone area is; and (2) on the choice of score whose maximization defines the optimal classifier. Such map is not the result of a transfer model (geogenic to indoor radon), but of the optimization of a classification rule. The method is computationally simple but has its caveats and statistical traps, some of which are also addressed. [Copyright &y& Elsevier]

Published

2014

30. Development of a Geogenic Radon Hazard Index—Concept, History, Experiences

Author

Tore Tollefsen, Peter Bossew, Giancarlo Ciotoli, Valeria Gruber, Marc De Cort, Quentin Crowley, Javier Elío Medina, Giorgia Cinelli, and Eric Petermann

Subjects

Radon mitigation, 010504 meteorology & atmospheric sciences, Concept History, Health, Toxicology and Mutagenesis, chemistry.chemical_element, lcsh:Medicine, Radon, Review, 010501 environmental sciences, 01 natural sciences, geogenic radon hazard index, Geogenic radon hazard index, Radiation Monitoring, Environmental planning, 0105 earth and related environmental sciences, lcsh:R, Public Health, Environmental and Occupational Health, Hazard index, Radiation Exposure, European map of geogenic radon, geogenic radon potential, Data availability, Europe, chemistry, Geogenic radon potential, Air Pollutants, Radioactive, Air Pollution, Indoor, Environmental science

Abstract

Exposure to indoor radon at home and in workplaces constitutes a serious public health risk and is the second most prevalent cause of lung cancer after tobacco smoking. Indoor radon concentration is to a large extent controlled by so-called geogenic radon, which is radon generated in the ground. While indoor radon has been mapped in many parts of Europe, this is not the case for its geogenic control, which has been surveyed exhaustively in only a few countries or regions. Since geogenic radon is an important predictor of indoor radon, knowing the local potential of geogenic radon can assist radon mitigation policy in allocating resources and tuning regulations to focus on where it needs to be prioritized. The contribution of geogenic to indoor radon can be quantified in different ways: the geogenic radon potential (GRP) and the geogenic radon hazard index (GRHI). Both are constructed from geogenic quantities, with their differences tending to be, but not always, their type of geographical support and optimality as indoor radon predictors. An important feature of the GRHI is consistency across borders between regions with different data availability and Rn survey policies, which has so far impeded the creation of a European map of geogenic radon. The GRHI can be understood as a generalization or extension of the GRP. In this paper, the concepts of GRP and GRHI are discussed and a review of previous GRHI approaches is presented, including methods of GRHI estimation and some preliminary results. A methodology to create GRHI maps that cover most of Europe appears at hand and appropriate; however, further fine tuning and validation remains on the agenda.

Published

2020

31. Detailed Geogenic Radon Potential Mapping Using Geospatial Analysis of Multiple Geo-Variables-A Case Study from a High-Risk Area in SE Ireland.

Author

Aghdam MM, Dentoni V, Da Pelo S, and Crowley Q

Subjects

Humans, Bayes Theorem, Soil, Radon analysis, Air Pollutants, Radioactive analysis, Radiation Monitoring methods, Soil Pollutants, Radioactive analysis, Air Pollution, Indoor analysis

Abstract

A detailed investigation of geogenic radon potential (GRP) was carried out near Graiguenamanagh town (County Kilkenny, Ireland) by performing a spatial regression analysis on radon-related variables to evaluate the exposure of people to natural radiation (i.e., radon, thoron and gamma radiation). The study area includes an offshoot of the Caledonian Leinster Granite, which is locally intruded into Ordovician metasediments. To model radon release potential at different points, an ordinary least squared (OLS) regression model was developed in which soil gas radon (SGR) concentrations were considered as the response value. Proxy variables such as radionuclide concentrations obtained from airborne radiometric surveys, soil gas permeability, distance from major faults and a digital terrain model were used as the input predictors. ArcGIS and QGIS software together with XLSTAT statistical software were used to visualise, analyse and validate the data and models. The proposed GRP models were validated through diagnostic tests. Empirical Bayesian kriging (EBK) was used to produce the map of the spatial distribution of predicted GRP values and to estimate the prediction uncertainty. The methodology described here can be extended for larger areas and the models could be utilised to estimate the GRPs of other areas where radon-related proxy values are available.

Published

2022

32. On the influence of faulting on small-scale soil-gas radon variability: a case study in the Iberian Uranium Province

Author

Pereira, A.J.S.C., Godinho, M.M., and Neves, L.J.P.F.

Subjects

*GEOLOGIC faults, *RADON, *SOIL air, *CASE studies, *URANIUM, *RADIATION measurements, *GAMMA rays, *GROUNDWATER & the environment

Abstract

Abstract: In order to evaluate the influence of faulting on the variability of geogenic radon at detailed scale (1:2000), data on gamma ray fluxes, U and Th concentrations in rocks, radon in soil-gas and radon in groundwater were collected in three target areas on the Oliveira do Hospital region (Central Portugal). This region stands on the Iberian Uranium Province, and is dominantly composed of Hercynian granites and metasedimentary rocks of pre-Ordovician age, crosscut by faults with dominant strike N35°E, N55°E and N75°E. Radiometric anomalies are frequent, associated with faults of the referred systems and metasedimentary enclaves; the analytical data confirms that these anomalies are produced by local high uranium contents in rocks and fault-filling materials (n =34, range 13–724ppm), while other radiogenic elements are relatively constant (e.g. Th 4–30ppm). Radon concentration in soil can be extremely high, up to 12,850kBqm−3 (n =215), with a large proportion of results above 100kBqm−3. Unsurprisingly, groundwater also shows high radon concentrations, with observed values in the range 150–4850Bq.L−1 (n =17). From the results it is concluded that metasedimentary enclaves, as well as faults, can accumulate uranium from circulating fluids, and as a consequence, strongly locally enhance geogenic radon potential. Due to this fact, for the purpose of land use planning in such uranium-enriched regions, very detailed geological mapping is needed to precisely recognize radon high risk areas. A correlation between radon concentration in soil or in groundwater and gamma ray fluxes was established pointing to the possible use of these fluxes as a first step in assessing geogenic radon potential, at least to geological setting similar to the study area. [Copyright &y& Elsevier]

Published

2010

33. The assessment of local geological factors for the construction of a Geogenic Radon Potential map using regression kriging. A case study from the Euganean Hills volcanic district (Italy).

Author

Coletti, Chiara, Ciotoli, Giancarlo, Benà, Eleonora, Brattich, Erika, Cinelli, Giorgia, Galgaro, Antonio, Massironi, Matteo, Mazzoli, Claudio, Mostacci, Domiziano, Morozzi, Pietro, Mozzi, Paolo, Nava, Jacopo, Ruggiero, Livio, Sciarra, Alessandra, Tositti, Laura, and Sassi, Raffaele

Published

2022

34. From radon hazard to risk prediction-based on geological maps, soil gas and indoor measurements in Germany.

Author

Kemski, J., Klingel, R., Siehl, A., and Valdivia-Manchego, M.

Subjects

RADON, ENVIRONMENTAL risk assessment, SOIL air, GEOLOGICAL maps, INDOOR air pollution research, GEOCHEMISTRY, SPATIAL analysis (Statistics)

Abstract

Mapped geological units can be regarded as proxies standing for a complex series of subsoil geochemical and physical properties including the assigned radon activity concentration in soil gas, which is taken as best estimator of the regional geogenic radon potential. Areal distribution of measuring sites for soil gas in Germany is adapted to spatial variation of geology. A grid-based and distance-weighted interpolation procedure is applied, following geologically defined neighbourhood relations of measuring sites and accounting for isolated outcrops of known geology but without measurements. To investigate the statistical relationship between indoor radon, house type and building ground specifications, measurements of the indoor radon concentration have been carried out in more than 10,000 dwellings in different regions of Germany. Multiple regression analyses of variance reveal that besides region-specific geological properties and building characteristics, various house type and living style variables significantly contribute to the explained variance for ground floor radon concentrations. These parameters are also dominant in controlling the radon transfer relation from soil gas to indoor air. Risk prediction maps for radon in houses indicating the probability to exceed certain indoor threshold values can be useful especially for regions with no or only a few measurements of indoor radon. [ABSTRACT FROM AUTHOR]

Published

2008

35. Batı Anadolu'yu tanımlayan Çine yöresinde jeolojik radon potansiyelinin belirlenmesi

Author

Sagözen, Zübeyir, Yaprak, Günseli, Fen Bilimleri Enstitüsü, and Nükleer Bilimler Anabilim Dalı

Subjects

Lithological Units, Batı Anadolu, Jeojenik Radon Potansiyeli, Geogenic Radon Potential, Nükleer Mühendislik, West Anatolia, Nuclear Engineering, Çine Asmasifi, Litolojik Birimler, Çine Submasif

Abstract

Jeolojik kökenli radon potansiyeli haritalanması fikri, insan kaynaklı aktivitelerden bağımsız, sadece doğal radon riskini göstermek için ortaya çıkmıştır. Radon konsantrasyonunu kontrol eden jeolojik faktörler; ana kayaç- toprağın U/Ra içeriği, toprak gazı radon ve radon salınım hızıdır. Faylar ve makaslama zonları gibi jeolojik faktörler, radon salınımını arttırmaktadırlar. Toprağın geçirgenlik, nem içeriği, partikül boyutu gibi özellikleri radon potansiyelini tayin etmede kritik öneme sahiptir. Bu doğrultuda, Orta-Batı Anadolu'da görülen bütün litolojik birimleri barındıran Çine bölgesinde jeolojik radon potansiyelini araştırmak amacıyla; farklı litolojik birimlerin bulunduğu 14 istasyon belirlenmiştir. İstasyonlardan alınan örneklerin radyometrik analizleri gerçekleştirilmiştir. Toprak gazı radon ölçümleri aktif ve pasif yöntem ile bu istasyonlarda yapılmıştır. Örneklerin radyo element konsantrasyonları incelenmiştir. Nükleer iz ölçümleriyle, meteorolojik veriler arasındaki korelasyon incelenmiştir. Parçacık boyutu analizine bağlı toprak geçirgenliği ile nükleer iz detektörleriyle ölçülen radon konsantrasyonları arasındaki ilişki One Way Anova ve Tukey Testi yöntemiyle incelenmiştir. Ana kayaç/topraktan radon salınım hızı, Çine asmasifinden alınan örneklerin 226Ra aktivitesine dayalı olarak hesaplanmıştır., The idea of geological radon potential mapping emerged to show only natural radon risk independent of human-induced activities. Geological factors controlling radon concentration are the U / Ra content of the bedrock-soil, radon concentration in soil gas and radon exhalation rate. Other geological factors such as faults and shear zones increase radon exhalation rate. Properties of soil such as permeability, moisture content, particle size are critical in determining radon potential. In this respect, in order to investigate geological radon potential in Çine region which contains all lithological units in Central-Western Anatolia; 14 stations with different lithological units were identified. Radiometric analyzes of samples taken from stations were performed. Soil gas radon measurements were made by active and passive methods at the stations. Radio - element concentrations of samples were investigated. The correlation between the measurements made by nuclear trace detectors and meteorological data was examined. The relationship between soil permeability determined by particle size analysis and radon concentrations measured by nuclear trace detectors was investigated by One Way Anova and Tukey Test method. Radon exhalation rate was calculated based on 226Ra activity in the samples

Published

2019

36. Estimation of the Radon Risk Under Different European Climates and Soil Textures.

Author

Gil-Oncina S, Valdes-Abellan J, Pla C, and Benavente D

Subjects

Soil, Water, Air Pollutants, Radioactive analysis, Radon analysis, Soil Pollutants, Radioactive analysis

Abstract

Radon is a radioactive gas produced from the natural radioactive decay of uranium and is found in almost all rocks and soils. In confined places (e.g., dwellings, workplaces, caves, and underground mines), radon may accumulate and become a substantial health risk since it is considered the second most important cause of lung cancer in many developed countries. Radon risk assessment commonly considers either field or estimate values of the radon concentration and the gas permeability of soils. However, radon risk assessment from single measurement surveys to radon potential largescale mapping is strongly sensitive to the soil texture variability and climate changes, and particularly, to the soil water content dynamic and its effect on soil gas permeability. In this paper, the gas permeability of soils, and thus, the estimation of radon risk, is studied considering the effect of three different climates following the Köppen classification and four soil textures on soil water content dynamics. This investigation considers the CLIGEN weather simulator to elaborate 100-year length climatic series; Rosseta 3 pedotransfer function to calculate soil hydraulics parameters, and the HYDRUS-1D software to model the dynamics of water content in the soil. Results reveal that climate strongly affects gas permeability of soils and they must be considered as an additional factor during the evaluation of radon exposure risk. The impact of climate and texture defines the soil water content dynamic. Coarse soils show smaller gas permeability variations and then radon risk, in this case, is less affected by the climate type. However, in clay soils, the effect of climate and the differences in soil water content derive in gas permeability variations between 100 and 1,000 times through an annual cycle. As a result, it may cross the boundary between two radon risk categories. Results deeply confirm that both climate and texture should be compulsory considered when calculating the radon exposure risk and in the definition of new strategies for the elaboration of more reliable geogenic radon potential largescale maps., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Gil-Oncina, Valdes-Abellan, Pla and Benavente.)

Published

2022

37. Radon Hazard in Central Italy: Comparison among Areas with Different Geogenic Radon Potential.

Author

Giustini F, Ruggiero L, Sciarra A, Beaubien SE, Graziani S, Galli G, Pizzino L, Tartarello MC, Lucchetti C, Sirianni P, Tuccimei P, Voltaggio M, Bigi S, and Ciotoli G

Subjects

Gamma Rays, Air Pollutants, Radioactive analysis, Air Pollution, Indoor analysis, Radiation Monitoring methods, Radon analysis, Soil Pollutants, Radioactive analysis

Abstract

Radon ( 222 Rn) is a natural radioactive gas formed in rocks and soil by the decay of its parent nuclide (238-Uranium). The rate at which radon migrates to the surface, be it along faults or directly emanated from shallow soil, represents the Geogenic Radon Potential (GRP) of an area. Considering that the GRP is often linked to indoor radon risk levels, we have conducted multi-disciplinary research to: (i) define local GRPs and investigate their relationship with associated indoor Rn levels; (ii) evaluate inhaled radiation dosages and the associated risk to the inhabitants; and (iii) define radon priority areas (RPAs) as required by the Directive 2013/59/Euratom. In the framework of the EU-funded LIFE-Respire project, a large amount of data (radionuclide content, soil gas samples, terrestrial gamma, indoor radon) was collected from three municipalities located in different volcanic districts of the Lazio region (central Italy) that are characterised by low to high GRP. Results highlight the positive correlation between the radionuclide content of the outcropping rocks, the soil Rn concentrations and the presence of high indoor Rn values in areas with medium to high GRP. Data confirm that the Cimini-Vicani area has inhalation dosages that are higher than the reference value of 10 mSv/y.

Published

2022

38. Mapping the geogenic radon potential and radon risk by using Empirical Bayesian Kriging regression: A case study from a volcanic area of central Italy

Author

Livio Ruggiero, Alessio Rinaldini, Mario Voltaggio, Francesca Giustini, and Giancarlo Ciotoli

Subjects

Environmental Engineering, 010504 meteorology & atmospheric sciences, Soil test, Indoor radon, Outcrop, chemistry.chemical_element, Radon, Soil science, 010501 environmental sciences, 01 natural sciences, Kriging, Soil gas, Environmental Chemistry, Waste Management and Disposal, 0105 earth and related environmental sciences, geography, Radionuclide, geography.geographical_feature_category, Bedrock, Risk prediction map, Pollution, chemistry, Volcano, Radon mapping, Environmental science, Geogenic Radon Potential

Abstract

A detailed geochemical study on radon related to local geology was carried out in the municipality of Celleno, a little settlement located in the eastern border of the Quaternary Vulsini volcanic district (central Italy). This study included soil-gas and terrestrial gamma dose rate survey, laboratory analyses of natural radionuclides (238U, 226Ra, 232Th, 40K) activity in rocks and soil samples, and indoor radon measurements carried out in selected private and public dwellings. Soil-gas radon and carbon dioxide concentrations range from 6 to 253 kBq/m3 and from 0.3 to11% v/v, respectively. Samples collected from outcropping volcanic and sedimentary rocks highlight: significant concentrations of 238U, 226Ra and 40K for lavas (151, 150 and 1587 Bq/kg, respectively), low concentrations for tuffs (126, 123 and 987 Bq/kg, respectively), and relatively low for sedimentary rocks (108, 109 and 662 Bq/kg, respectively). Terrestrial gamma dose rate values range between 0.130 and 0.417 μSv/h, being in good accordance with the different bedrock types. Indoor radon activity ranges from 162 to 1044 Bq/m3; the calculated values of the annual effective dose varied from 4.08 and 26.31 mSv/y. Empirical Bayesian Kriging Regression (EBKR) was used to develop the Geogenic Radon Potential (GRP) map. EBKR provided accurate predictions of data on a local scale developing a spatial regression model in which soil-gas radon concentrations were considered as the response variable; several proxy variables, derived from geological, topographic and geochemical data, were used as predictors. Risk prediction map for indoor radon was tentatively produced using the Gaussian Geostatistical Simulation and a soil-indoor transfer factor was defined for a ‘standard’ dwelling (i.e., a dwelling with well-defined construction properties). This approach could be successfully used in the case of homogeneous building characteristics and territory with uniform geological characteristics.

Published

2018

39. GIS-based interpolation methods for spatial assessment of Geogenic Radon Potential

Author

Francesca Giustini, Giancarlo Ciotoli, Livio Ruggiero, and Mario Voltaggio

Subjects

Geogenic Radon Potential, GIS, Interpolation

Abstract

Modelling the spatial variability of Geogenic Radon Potential (GRP), based on spatially continuous geological, geographical and geochemical information as proxy data, is an important task to identify radon-prone areas and provide the local administration of a useful tool for land use planning and strategies aimed at radon health risk reduction. In this work, different interpolation techniques in a geographical information system (GIS) environment are applied and compared for estimating the spatial variation of GRP in the municipality of Celleno (Lazio, central Italy). The research activity has been conducted within the European LIFE-Respire project. Three regression models such as Ordinary Least Squares regression (OLS), Geographically Weighted Regression (GWR) and Empirical Bayesian Regression Kriging (EBRK) were applied to investigate the relationships between soil-gas radon concentrations and some proxy explanatory variables, and to generate spatial distribution of GRP. Ordinary Least Squares uses traditional regression techniques to model the relationships between a dependent variable and a set of independent variables (i.e. the explanatory variables). It provides a global model of the studied variable and creates a single regression equation to represent a process; this regression method assumes the relationship is constant over space, so the estimated coefficients of the regression are the same for all the study area. Geographically Weighted Regression is an extension of the traditional OLS regression, but it does assume that the relationships among the independent variables are not constant over space, then GWR calculates local regression coefficients and local r-squared values (R2) rather than global parameters. Finally, Empirical Bayesian Regression Kriging is a geostatistical interpolation that uses explanatory variables in raster format to improve predictions of the dependent variable. Regression models and semivariograms are estimated locally with simulations; and explanatory variables are transformed into principle components prior to modelling to solve multicollinearity problems. The regression models have been performed using the following proxy (i.e., explanatory) variables: the natural content of the radiogenic elements (Ra, U, Th, and K), the emanation coefficient of the outcropping rocks, the diffusive 222Rn flux from the soil, the soil-gas CO2 concentration, the Digital Terrain Model (DTM) and Topographic Position Index (TPI, a DTM-derived morphometric parameter), the permeability of the outcropping rocks (derived from the map of the hydrological complexes) and the gamma dose radiation of the shallow lithology. Soil-gas radon measurements were used as the response (i.e., dependent) variable of the applied regression models. Data has been organised in two subsets (training and test data) to be used in the validation process. Results from validation technique indicate that GWR provides a local model with a better performance (adjusted R2=0.882) than the global OLS model (adjusted R2=0.573). However, the application of the EBRK will result in the best model validation (R2=0.989) vs the validation of the GWR result (R2=0.863). Research was conducted and funded within two research projects: INAIL/CNR-IGAG (P19L06) and LIFE-Respire (LIFE16 ENV/IT/000553).

Published

2018

40. Ambient gamma dose rate as an indicator of geogenic radon potential.

Author

Tchorz-Trzeciakiewicz, D.E. and Rysiukiewicz, M.

Abstract

Radon is the second cause of lung cancer after smoking, therefore is acknowledged as a major indoor air pollutant. Geogenic radon potential indicates regions where for natural reasons elevated indoor radon levels or elevated probability of their occurrence can be expected. The most common procedure for establishing geogenic radon potential includes measurements of soil permeability and soil gas radon concentrations. These measurements are time-consuming and expensive therefore a limited number of measurements is carried out and their results are extrapolated to the specific area. Our research aimed to analyse the usefulness of ambient gamma dose rate survey to assess radon concentration in the environment and therefore geogenic radon potential. The measurements were carried out on two granite massifs with higher (Karkonosze) and lower (Strzelin) radioactive elements contents. Seasonal variations of atmospheric radon concentrations and ambient gamma dose rates were registered with higher values during warmer and lower during colder seasons. The opposite seasonal variations were observed for soil gas radon concentrations. No distinctive seasonal variations were recorded in results of uranium, thorium and potassium contents in soil measured in situ by the gamma-ray spectrometer. The correlation coefficients were calculated on the base of annual average data. The correlations between ambient gamma dose rate and radon concentration in soil and in the atmosphere were 0.83 and 0.62 respectively, which may suggest that ambient gamma dose rate can be a useful parameter to indicate geogenic radon potential. Unlabelled Image • Ambient gamma dose rate - an efficient indicator of geogenic radon potential • Seasonal variations of atmospheric radon concentrations • Seasonal variations of soil radon concentrations • Seasonal variations of ambient gamma dose rate • Lack of seasonal variations in in-situ survey of U, Th, K-40 [ABSTRACT FROM AUTHOR]

Published

2021

41. Mapping the geogenic radon potential for Germany by machine learning.

Author

Petermann, Eric, Meyer, Hanna, Nussbaum, Madlene, and Bossew, Peter

Abstract

The radioactive gas radon (Rn) is considered as an indoor air pollutant due to its detrimental effects on human health. In fact, exposure to Rn belongs to the most important causes for lung cancer after tobacco smoking. The dominant source of indoor Rn is the ground beneath the house. The geogenic Rn potential (GRP) - a function of soil gas Rn concentration and soil gas permeability - quantifies what "earth delivers in terms of Rn" and represents a hazard indicator for elevated indoor Rn concentration. In this study, we aim at developing an improved spatial continuous GRP map based on 4448 field measurements of GRP distributed across Germany. We fitted three different machine learning algorithms, multivariate adaptive regression splines, random forest and support vector machines utilizing 36 candidate predictors. Predictor selection, hyperparameter tuning and performance assessment were conducted using a spatial cross-validation where the data was iteratively left out by spatial blocks of 40 km*40 km. This procedure counteracts the effect of spatial auto-correlation in predictor and response data and minimizes dependence of training and test data. The spatial cross-validated performance statistics revealed that random forest provided the most accurate predictions. The predictors selected as informative reflect geology, climate (temperature, precipitation and soil moisture), soil hydraulic, soil physical (field capacity, coarse fraction) and soil chemical properties (potassium and nitrogen concentration). Model interpretation techniques such as predictor importance as well as partial and spatial dependence plots confirmed the hypothesized dominant effect of geology on GRP, but also revealed significant contributions of the other predictors. Partial and spatial dependence plots gave further valuable insight into the quantitative predictor-response relationship and its spatial distribution. A comparison with a previous version of the German GRP map using 1359 independent test data indicates a significantly better performance of the random forest based map. Unlabelled Image • Mapping of the geogenic radon potential as hazard indicator for indoor radon • Comparison of three machine learning algorithms • Application of spatial cross-validation using spatial blocks to split the data • Partial and spatial dependence plots reveal predictor-response relationship • Random forest GRP map outperforms previous maps using geostatistics [ABSTRACT FROM AUTHOR]

Published

2021

42. Farklı metamorfik birimlerde aktif karbonla toprak gazı radon ölçümü ve radon potansiyelini etkileyen parametrelerin incelenmesi

Author

Gürleyen, Serkan, Saç, Müslim Murat, Nükleer Bilimler Anabilim Dalı, Saç, Müslim, Murat, and Fen Bilimleri Enstitüsü

Subjects

Pedolojik Faktörler, Activated Charcoal Canister, Jeolojik Radon Potansiyeli, Aktif Karbon, Uranyum/Radyum, Toprak Gazı Radon Aktivitesi, Pedological Factors, Geogenic Radon Potential, Nükleer Mühendislik, Nuclear Engineering, Radon Activity İn Soil Gas, Uranium/Radium

Abstract

Jeolojik kökenli (jeojenik) radon potansiyeli, bina yapım özelliklerinden bağımsız, bina içi radonun en olası kaynağı olarak tanımlanmaktadır. Ana kayaç/ toprağın Ra içeriği, toprak gazı radon ve ana kayaç/topraktan radon salınım hızı, yeryüzüne radon göçü ve radon riski için iyi bir jeokimyasal işarettir. Jeolojik radon potansiyeli aynı jeolojik birim içinde küçük değişimler göstermekte, ancak yerel ölçekte, pedolojik (toprakların, nem, geçirgenlik, parçacık boyutu gibi fiziksel özellikleri) faktörlerden etkilenmektedir. Bu çalışmada, Batı Anadolu'ya özgü bütün yapısal ve litolojik unsurları içeren Çine yöresinde, farklı metamorfik birimlerde jeolojik radon potansiyeli ve/veya yer seviyesinde antropojenik aktivitelerden bağımsız radon konsantrasyonu; jeolojik bilgi, jeokimyasal analiz, arazi ve laboratuvarda aktif karbon kolektörü kullanılarak değerlendirilmiş ve jeolojik radon potansiyelini etkileyen parametreler incelenmiştir., The geogenic radon potential is the essential parameter describing the subsurface as the main source for the indoor radon concentrations independent on the construction features of buildings. In general, uranium/ radium contents of soils, radon activity in soil gas and also radon emanation are all good geochemical indicators of radon risk. In the same lithology, noticeable differences in radon levels can occur independently of lithology (possibly caused pedological factors such as moisture content, permeability, particle size and etc.). The aim of the study is therefore evaluation of the geological radon potential on the basis of the interpretation of the geological, geochemical and pedological data and radiometric measurements including soil gas radon measurements using activated charcoal canister for the Çine region as representative of West Anatolia lithology.

Published

2017

43. Geogenic Radon Potential map of the Celleno municipality (Lazio, central Italy)

Author

1 Francesca Giustini, 1 Giancarlo Ciotoli, 2 Alessio Rinaldini, 3 Livio Ruggiero, and 1 Mario Voltaggio

Subjects

Celleno municipality (VT), Geogenic Radon Potential

Abstract

In the international literature new methodological approaches and modelling, based on spatially continuous geological and environmental radon proxy parameters (e.g., lithology, permeability and airborne total gamma radiation), were recently proposed to construct maps of the Geogenic Radon Potential (GRP) in order to identify radon-prone areas. In this work are presented data collected in the municipality of Celleno (VT) that was selected for a detailed study within the framework of the research project INAIL/CNR- IGAG P19L06 "Studio dei processi di migrazione e accumulo dei gas endogeni e del radon dai suoli verso gli ambienti di vita e di lavoro in funzione delle caratteristiche geologiche presenti al contorno". The aims of the project were: 1) to investigate the main factors affecting the GRP at local scale through the development of a spatial regression model considering soil-gas radon concentrations as the response variable and developing proxy variables as predictors; 2) to construct a map of the GRP, thus providing the local administration of a useful tool for land use planning and strategies aimed at radon health risk reduction; 3) to use a soil-indoor transfer factor to discriminate the amount of the geogenic radon vs the rate due to building and habit characteristics. The study area is located along the western margin of central Italy characterized by extensional tectonics, high heat flow and widespread CO2 gas emissions. The municipality of Celleno extends on a surface of about 25 km2 and is located 80 km NW of Rome, at the eastern border of the Quaternary Vulsini volcanic district, whose activity produced mainly pyroclastic products and minor lava flows with potassic to ultrapotassic affinity. The outcropping volcanic rocks were traditionally used as building materials in the old center of the Celleno village. Soil-gas surveys and laboratory analyses were carried out to measure the concentrations of radon and other endogenic gases in the shallow environment, as well as the activity concentrations of natural radionuclides (238U, 226Ra, 232Th, 40K) and the radon emanation coefficient of several soil and rock samples, representative of the different lithotypes outcropping in the area. Indoor radon measurements were also carried out in selected private and public dwellings and cellars. Soil gas 222Rn concentrations range from 6 to 253 kBq/m3; CO2 concentrations range between 0.3% and 11%. Samples collected from outcropping volcanic and sedimentary rocks highlight: significant concentrations of 238U, 226Ra and 40K for lavas (183, 181 and 1671 Bq/kg, respectively), lower concentrations for tuffs (110, 92 and 756 Bq/kg, respectively) and very low for sedimentary rocks (42, 47 and 572 Bq/kg, respectively). Indoor radon activity ranges from 162 to 1044 Bq/m3, the highest value (4256 Bq/m3) was collected in a cellar directly carved into a tuff deposit. About 50% of the measured dwellings show radon indoor values above 300 Bq/m3 (threshold value recommended in the 2013/59/Euratom Directive), whereas all investigated sites show radon indoor values above 100 Bq/m3. Classical (Ordinary Least Square, OLS) and spatial (Geographically Weighted Regression, GWR) regression models were applied to investigate the relationships between soil-gas radon concentrations and some proxy explanatory variables, and to construct the GRP map. The OLS regression highlights that CO2 concentrations in soil gas, 226Ra content, radon emanation coefficient and Digital Terrain Model are statistical significant in the model. These variables were used to improve the model performances within GWR. The final map shows areas with high GRP on the western sector of the municipality of Celleno; as this area is sparsely populated, the GPR map may facilitate the future urban planning and should allow the improvement of public health management strategies. A radon soil-indoor transfer factor was calculated to discriminate the geogenic vs indoor contribution. Preliminary results highlight that ventilation habits and building materials (mainly tuff) appear to be important parameters affecting the radon accumulation. According to these promising results, the Celleno municipality has been selected and further investigated within the new LIFE-Respire project.

Published

2017

44. Development of a Geogenic Radon Hazard Index-Concept, History, Experiences.

Author

Bossew P, Cinelli G, Ciotoli G, Crowley QG, De Cort M, Elío Medina J, Gruber V, Petermann E, and Tollefsen T

Subjects

Europe, Air Pollutants, Radioactive, Air Pollution, Indoor, Radiation Exposure standards, Radiation Monitoring, Radon

Abstract

Exposure to indoor radon at home and in workplaces constitutes a serious public health risk and is the second most prevalent cause of lung cancer after tobacco smoking. Indoor radon concentration is to a large extent controlled by so-called geogenic radon, which is radon generated in the ground. While indoor radon has been mapped in many parts of Europe, this is not the case for its geogenic control, which has been surveyed exhaustively in only a few countries or regions. Since geogenic radon is an important predictor of indoor radon, knowing the local potential of geogenic radon can assist radon mitigation policy in allocating resources and tuning regulations to focus on where it needs to be prioritized. The contribution of geogenic to indoor radon can be quantified in different ways: the geogenic radon potential (GRP) and the geogenic radon hazard index (GRHI). Both are constructed from geogenic quantities, with their differences tending to be, but not always, their type of geographical support and optimality as indoor radon predictors. An important feature of the GRHI is consistency across borders between regions with different data availability and Rn survey policies, which has so far impeded the creation of a European map of geogenic radon. The GRHI can be understood as a generalization or extension of the GRP. In this paper, the concepts of GRP and GRHI are discussed and a review of previous GRHI approaches is presented, including methods of GRHI estimation and some preliminary results. A methodology to create GRHI maps that cover most of Europe appears at hand and appropriate; however, further fine tuning and validation remains on the agenda.

Published

2020

45. Indoor radon and geogenic radon potential mapping of certain counties with elevated radon values in Croatia

Author

Radolić, Vanja, Miklavčić, Igor, Poje Sovilj, Marina, Stanić, Denis, Mužević, Matko, Krpan, Ivana, and Vuković, Branko

Subjects

Indoor radon, Geogenic radon potential, Radon mapping

Abstract

A national survey of indoor radon levels in Croatia was performed during 2003/2004 by LR-115 II track etched detectors and the average value of 68 Bq/m3 was obtained [1]. In the last few years, the targeted surveys of indoor radon in homes as well as public buildings with high occupancy (kindergartens and schools) were performed in some counties with radon values above average (Lika-Senj, Karlovac, Istria counties). Detectors were randomly distributed in homes across the whole geographic areas and the number of detectors depended on population densities of the investigated areas. The obtained average values were higher for Karlovac and Istria Counties (151 Bq/m3 and 105 Bq/m3, respectively) in comparison with the national survey results ten years ago (104 Bq/m3 and 76 Bq/m3, respectively) since more detectors were exposed in newly identified areas with elevated radon levels. The average radon values in kindergartens and schools were 1.6 and 1.9 times higher than in homes in the investigated areas. In Lika-Senj County both values exceed the highest recommended reference value of 300 Bq/m3 for radon in public buildings with high occupancy (kindergartens and schools) according to EU BSS. Radon concentrations in soil gas in these areas were measured with the AlphaGUARD and RM-2 measuring system. The soil permeability was measured by Radon-JOK permeameter in Istria County while in Lika-Senj and Karlovac Counties it was estimated as low, medium or high regarding the time necessary for soil gas sampling. A detailed geogenic radon potential (GRP) mapping based on field soil gas radon and soil gas permeability measurements was carried out. The relationship between GRP and indoor radon measurements in homes, kindergartens and schools were examined. According to the obtained results areas with elevated indoor radon levels in homes, kindergartens and schools as well as high GRP were identified [2]. The criteria for identification of “radon prone area” as part of the future National Action Plan for radon is proposed and discussed.

Published

2015

46. From radon hazard to risk prediction-based on geological maps, soil gas and indoor measurements in Germany

Author

Kemski, J., Klingel, R., Siehl, A., and Valdivia-Manchego, M.

Published

2009

47. Mapping of the geogenic radon potential in France to improve radon risk management: Methodology and first application to region Bourgogne

Author

Michel Cuney, M.E. Cushing, Géraldine Ielsch, Ph Combes, Institut de Radioprotection et de Sûreté Nucléaire (IRSN), GEOTER SAS, FUGRO Group, Géologie et gestion des ressources minérales et énergétiques (G2R), and Université Henri Poincaré - Nancy 1 (UHP)-Institut National Polytechnique de Lorraine (INPL)-Centre de recherches sur la géologie des matières premières minérales et énergétiques (CREGU)-Centre National de la Recherche Scientifique (CNRS)

Subjects

010504 meteorology & atmospheric sciences, Health, Toxicology and Mutagenesis, air pollution, 010501 environmental sciences, boundary layer, radioactive pollution, 01 natural sciences, regulatory approach, Bourgogne, Radon level, Waste Management and Disposal, Radioactive, Risk management, Air Pollutants, Radiation, article, risk assessment, radon, methodology, General Medicine, Pollution, Radioactivity, Geogenic radon potential, Mapping, Radon mapping, France, radiation monitoring, geology, chemistry.chemical_element, Soil science, Radon, Environment, Geological data, risk management, soil, uranium, Natural hazard, Radioactive contamination, Environmental Chemistry, Natural radioactivity, 0105 earth and related environmental sciences, soil pollution, Preferential pathways, business.industry, Radon source, mapping method, audiovisual equipment, Fault line, Priority areas, Geological units, geogenic source, chemistry, Air Pollutants, Radioactive, [SDU]Sciences of the Universe [physics], atmosphere, Environmental science, Zoning, Scale (map), business, Transuranium elements

Abstract

cited By 68; In order to improve regulatory tools for radon risk management in France, a harmonised methodology to derive a single map of the geogenic radon potential has been developed. This approach consists of determining the capacity of the geological units to produce radon and to facilitate its transfer to the atmosphere, based on the interpretation of existing geological data. This approach is firstly based on a classification of the geological units according to their uranium (U) content, to create a radon source potential map. This initial map is then improved by taking into account the main additional parameters, such as fault lines, which control the preferential pathways of radon through the ground and which can increase the radon levels in soils. The implementation of this methodology to the whole French territory is currently in progress. We present here the results obtained in one region (Bourgogne, Massif Central) which displays significant variations of the geogenic radon potential. The map obtained leads to a more precise zoning than the scale of the existing map of radon priority areas currently based solely on administrative boundaries. © 2010 Elsevier Ltd.

Published

2010

48. A statistical evaluation of the influence of housing characteristics and geogenic radon potential on indoor radon concentrations in France.

Author

Demoury C, Ielsch G, Hemon D, Laurent O, Laurier D, Clavel J, and Guillevic J

Subjects

France, Air Pollutants, Radioactive analysis, Air Pollution, Indoor analysis, Housing, Radon analysis

Abstract

Radon-222 is a radioactive natural gas produced by the decay of radium-226, known to be the main contributor to natural background radiation exposure. Effective risk management needs to determine the areas in which the density of buildings with high radon levels is likely to be highest. Predicting radon exposure from the location and characteristics of a dwelling could also contribute to epidemiological studies. Beginning in the nineteen-eighties, a national radon survey consisting in more than 10,000 measurements of indoor radon concentrations was conducted in French dwellings by the Institute for Radiological Protection and Nuclear Safety (IRSN). Housing characteristics, which may influence radon accumulation in dwellings, were also collected. More recently, the IRSN generated a French geogenic radon potential map based on the interpretation of geological features. The present study analyzed the two datasets to investigate the factors influencing indoor radon concentrations using statistical modeling and to determine the optimum use of the information on geogenic radon potential that showed the best statistical association with indoor radon concentration. The results showed that the variables associated with indoor radon concentrations were geogenic radon potential, building material, year of construction, foundation type, building type and floor level. The model, which included the surrounding geogenic radon potential (i.e. the average geogenic radon potential within a disc of radius 20 km centered on the indoor radon measurement point) and variables describing house-specific factors and lifestyle explained about 20% of the overall variability of the logarithm of radon concentration. The surrounding geogenic radon potential was fairly closely associated with the local average indoor radon concentration. The prevalence of exposure to radon above specific thresholds and the average exposures to radon clearly increased with increasing classes of geogenic radon potential. Combining the two datasets enabled improved assessment of radon exposure in a given area in France., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013