AI Article Synopsis
- Rare-earth elements (REEs) are emerging pollutants, yet their geochemistry in rivers affected by ion-adsorption mining is understudied.
- Samples collected from a mining-impacted river showed significantly higher concentrations of REEs in smaller water fractions (<0.45 μm) compared to a control site, with varying factors affecting REE distribution between upstream and downstream.
- The study found that upstream REE transport was influenced by ligand complexation and smaller colloids, while downstream concentrations were driven by larger colloids and particle adsorption, highlighting the importance of REE patterns for understanding their behavior in mining-affected areas.
Article Abstract
Rare-earth elements (REEs) are known to be a group of emerging pollutants, but the geochemistry of REEs in river waters in ion-adsorption rare-earth mining areas has attracted little attention. In this study, samples of the <0.45 μm and 0.22-0.45 μm (large colloids) water fractions and acid-soluble particles (ASPs) were collected from a river impacted by ion-adsorption rare-earth mining activities. The roles of ligand complexation, colloid binding, and particle adsorption in REE transport and distribution were also investigated. Results showed higher concentrations of REEs in the <0.45 μm fraction of all sampling sites (3.30 × 10-9.42 μM) compared with that in the control site (1.21 × 10 μM); this fraction was also characterized by middle REE enrichment at upstream sites, where REEs are mainly controlled by the <0.22 μm fraction (55%-94% of the species found in the <0.45 μm fraction) and ligand complexation (REE, REE(SO), and REE(CO)). At downstream sites, heavy REE enrichment was observed, which was largely determined by binding to large colloids (68%-83% of the species found in the <0.45 μm fraction) and adsorption to particles (>90% of the acidified bulk water). Furthermore, REE patterns indicated that the REE-associated large colloids were mineral or mixed mineral-organic matter (OM) at upstream sites and OM-dominated or functionalized at downstream sites. The particles were mainly coated by inorganic matter substances (e.g., Fe/Al oxyhydroxides). In summary, our results reveal that REE patterns provide a useful tool to study the fate of REEs in ion-adsorption rare-earth mining catchments.
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| http://dx.doi.org/10.1016/j.scitotenv.2019.01.076 | DOI Listing |
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