The Phosphorus Transport in Groundwater from Phosphogypsum-Based Cemented Paste Backfill in a Phosphate Mine: A Numerical Study

Stacked phosphogypsum (PG) can not only cause a waste of resources but also has a serious negative impact on the surface environment. Phosphogypsum backfilling (PGB) in the underground goaf is a useful approach to effectively address the PG environmental problems. However, the effects of this approa...

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Published inInternational journal of environmental research and public health Vol. 19; no. 22; p. 14957
Main Authors Chen, Qiusong, Zhou, Huibo, Liu, Yikai, Wang, Daolin
Format Journal Article
LanguageEnglish
Published Switzerland MDPI AG 13.11.2022
MDPI
Subjects
Aquifers
Backfill
Contaminants
Dispersion
Ditches
Drainage
Drainage ditches
Geology
Groundwater
Groundwater flow
Leachates
Leaching
Mathematical models
Phosphates
Phosphogypsum
Phosphorus
Pollutants
Pollution transport
Precipitation
Simulation
Soil contamination
Surface water
Topography
Toxicity
Transport processes
Water flow
Anhui China
China
leaching
phosphorus transport
phosphogypsum
green mine
cemented paste backfilling
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Summary:Stacked phosphogypsum (PG) can not only cause a waste of resources but also has a serious negative impact on the surface environment. Phosphogypsum backfilling (PGB) in the underground goaf is a useful approach to effectively address the PG environmental problems. However, the effects of this approach on the groundwater environment have not been studied. Therefore, the present study aims to assess the spatiotemporal evolution mechanism of total phosphorus (TP) in groundwater to solve the diffusion regular pattern of TP in PGB bodies, as well as to manage and mitigate the impacts of TP on the groundwater system. In this study, leaching toxicity experiments and a numerical groundwater simulation software (GMS10.4) were combined to develop a three-dimensional conceptual model for predicting the groundwater flow and contaminant transport under steady-state conditions in a phosphorus mine in Anhui. The results showed a lower TP concentration than the TP standard concentration (0.2 mg/L) at a source concentration of 0.59 mg/L. However, groundwater TP source concentrations of 1.88 and 2.46 mg/L in the study area were found to exceed the standard concentration for a certain time and areas. In addition, the transport and dispersion of TP are influenced not only by the groundwater flow field, drainage ditches, rivers, and wells but also by the adsorption and attenuation effects of the soil that occur during the transport process, affecting the dispersion distance and distribution of groundwater TP concentrations. The results of the present study can promote the development of groundwater-friendly PGB technology, providing a great significance to the construction of green mines and the promotion of ecological civilization.
ISSN:1660-4601
1661-7827
1660-4601
DOI:10.3390/ijerph192214957