Sorrentina Peninsula: Geographical Distribution of the Indoor Radon Concentrations in Dwellings-Gini Index Application

The radon isotope (Rn-222, half-life 3.8 days) is a radioactive byproduct of the U-238 decay chain. Because radon is the second biggest cause of lung cancer after smoking, dense maps of indoor radon concentration are required to implement effective locally based risk reduction strategies. In this regard, we present an innovative method for the construction of interpolated maps (kriging) based on the Gini index computation to characterize the distribution of Rn concentration. The Gini coefficient variogram has been shown to be an effective predictor of radon concentration inhomogeneity. It allows for a better constraint of the critical distance below which the radon geological source can be considered uniform, at least for the investigated length scales of variability; it also better distinguishes fluctuations due to environmental predisposing factors from those due to random spatially uncorrelated noise. This method has been shown to be effective in finding larger-scale geographical connections that can subsequently be connected to geological characteristics. It was tested using real dataset derived from indoor radon measurements conducted in the Sorrentina Peninsula in Campania, Italy. The measurement was carried out in different residences using passive detectors (CR-39) for two consecutive semesters, beginning in September-November 2019 and ending in September-November 2020, to estimate the yearly mean radon concentration. The measurements and analysis were conducted in accordance with the quality control plan. Radon concentrations ranged from 25 to 722 Bq/m(3) before being normalized to ground level, and from 23 to 933 Bq/m(3) after being normalized, with a geometric mean of 120 Bq/m(3) and a geometric standard deviation of 1.35 before data normalization, and 139 Bq/m(3) and a geometric standard deviation of 1.36 after data normalization. Approximately 13% of the tests conducted exceeded the 300 Bq/m(3) reference level set by Italian Legislative Decree 101/2020. The data show that the municipalities under investigation had no influence on indoor radon levels. The geology of the monitored location is interesting, and because soil is the primary source of Rn, risk assessment and mitigation for radon exposure cannot be undertaken without first analyzing the local geology. This research examines the spatial link among radon readings using the mapping based on the Gini method (kriging).

Automated summary

The research presents an innovative method for constructing interpolated maps of radon concentration using the Gini index and kriging, which has been shown to effectively predict the distribution of radon concentration. The study demonstrates the spatial link between radon readings and geological characteristics, highlighting the importance of analyzing local geology in assessing and mitigating radon exposure risk.