可渗透反应墙
环境科学
环境化学
废物管理
环境工程
水处理
化学
污染
环境修复
工程类
生态学
生物
作者
Morgane Desmau,Elliott K. Skierszkan,Gladys Azaria Oka,Inderjeet Kaur,Valerie A. Schoepfer,David Flather,Guillaume Nielsen
出处
期刊:Chemosphere
[Elsevier BV]
日期:2025-06-14
卷期号:384: 144499-144499
标识
DOI:10.1016/j.chemosphere.2025.144499
摘要
Permeable reactive barriers (PRB) effectively attenuate multiple groundwater contaminants in temperate climates, but their efficacy remains uncertain in sub(Arctic) climates where cold temperatures inhibit kinetic biogeochemical reactions governing contaminant removal. This study applies bench-scale columns mimicking PRBs, containing varying proportions of zero-valent iron (ZVI), gravel, and wood chips, to treat synthetic mine-impacted water containing nitrate, arsenic, and uranium at low temperatures (5 °C) over 36 weeks. Columns were amended with sodium acetate during weeks 20-33 to stimulate microbial activity. Speciation was investigated by combining X-ray Absorption Spectroscopy and geochemical speciation modeling using PHREEQC. Arsenic removal efficiency exceeded 95 % over the experimental duration in all ZVI-bearing columns and was mostly driven by adsorption and coprecipitation with ZVI oxidation products. Nitrate removal was limited in the absence of acetate amendments but improved to ∼50 % during the amendment. Denitrification to N2 gas was incomplete, likely due to kinetic limitations on the various nitrogen reduction reaction steps. Uranium removal was >95 % in ZVI-bearing columns before the acetate amendment and was predominantly explained by U(VI) adsorption onto Fe-(oxyhydr)oxides. However, U was remobilized during the amendment, likely due to increased aqueous complexation of U by calcium and carbonate that drove the desorption of U from Fe-(oxyhydr)oxides. These experiments show that PRB technology holds promise for multi-contaminant removal under cold conditions, while exposing ongoing challenges associated with concurrent removal of contaminants exhibiting contrasting geochemical behavior.
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