In the last decades radon (Rn) has been widely proposed as a naturally occurring tracer for non-aqueous phase liquids (NAPL) in the soil. This work examines the feasibility of using soil gas data collected at some distance from the source zone for the application of the Rn deficit technique for the identification and quantification of NAPL contamination. To this end, we used a steady-state 1-D analytical solution that is based on a 3-layer model that allows to simulate the transport and distribution of Rn in the source zone, capillary fringe and overlying unsaturated soil. The analytical solution was first validated against a more detailed numerical model available in the literature. Then, a series of simulations were carried out to evaluate the vertical concentration profiles of Rn in soil gas above the source zone and in background location not impacted by NAPL. Simulation results showed that the parameters that most influence the migration and distribution of Rn in the subsurface are the distance of the soil gas probe from the source zone and, to a lower extent, the type of contamination (e.g. diesel or gasoline) and the soil type. On the basis of these results, we developed some easy-to-use nomographs to estimate the residual NAPL phase based on the observed radon deficit in soil gas and on the probe to source distance and soil and NAPL characteristics. According to the obtained results, the radon deficit technique results a feasible method for a qualitative identification of residual NAPL when radon in soil gas is measured at distances lower than 2 m from the contaminated zone. However, for an accurate quantitative estimation of the NAPL phase content, soil gas probes should be preferably located at distances lower than 1 m from the source zone.

Cecconi, A., Verginelli, I., Baciocchi, R. (2022). Modeling of soil gas radon as an in situ partitioning tracer for quantifying LNAPL contamination. SCIENCE OF THE TOTAL ENVIRONMENT, 806(Pt 2) [10.1016/j.scitotenv.2021.150593].

Modeling of soil gas radon as an in situ partitioning tracer for quantifying LNAPL contamination

Verginelli I.
;
Baciocchi R.
2022-01-01

Abstract

In the last decades radon (Rn) has been widely proposed as a naturally occurring tracer for non-aqueous phase liquids (NAPL) in the soil. This work examines the feasibility of using soil gas data collected at some distance from the source zone for the application of the Rn deficit technique for the identification and quantification of NAPL contamination. To this end, we used a steady-state 1-D analytical solution that is based on a 3-layer model that allows to simulate the transport and distribution of Rn in the source zone, capillary fringe and overlying unsaturated soil. The analytical solution was first validated against a more detailed numerical model available in the literature. Then, a series of simulations were carried out to evaluate the vertical concentration profiles of Rn in soil gas above the source zone and in background location not impacted by NAPL. Simulation results showed that the parameters that most influence the migration and distribution of Rn in the subsurface are the distance of the soil gas probe from the source zone and, to a lower extent, the type of contamination (e.g. diesel or gasoline) and the soil type. On the basis of these results, we developed some easy-to-use nomographs to estimate the residual NAPL phase based on the observed radon deficit in soil gas and on the probe to source distance and soil and NAPL characteristics. According to the obtained results, the radon deficit technique results a feasible method for a qualitative identification of residual NAPL when radon in soil gas is measured at distances lower than 2 m from the contaminated zone. However, for an accurate quantitative estimation of the NAPL phase content, soil gas probes should be preferably located at distances lower than 1 m from the source zone.
2022
Pubblicato
Rilevanza internazionale
Articolo
Esperti anonimi
Settore ICAR/03 - INGEGNERIA SANITARIA - AMBIENTALE
English
NAPL delineation
Radon deficit technique
Reactive transport modeling
Soil gas monitoring
Gasoline
Soil
Radon
Soil Pollutants
Water Pollutants, Chemical
https://reader.elsevier.com/reader/sd/pii/S0048969721056710?token=249A7BD9FD49069073A6476E9C98A52E3DC8FD6F2FD375DE3C59B04F2BFEFAD32F1E4CBFB79B070DA301DEABBB7FE9D5&originRegion=eu-west-1&originCreation=20220322155056
Cecconi, A., Verginelli, I., Baciocchi, R. (2022). Modeling of soil gas radon as an in situ partitioning tracer for quantifying LNAPL contamination. SCIENCE OF THE TOTAL ENVIRONMENT, 806(Pt 2) [10.1016/j.scitotenv.2021.150593].
Cecconi, A; Verginelli, I; Baciocchi, R
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2108/292139
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