环境修复
解吸
地下水修复
环境科学
污染
地下水
过程(计算)
废物管理
污染物
环境化学
化学
环境工程
吸附
地质学
岩土工程
计算机科学
工程类
生态学
有机化学
生物
操作系统
作者
Cong Han,Xiaobin Zhu,Guiyao Xiong,Jingxun Gao,Jianfeng Wu,Dong Wang,Jichun Wu
出处
期刊:Water Research
[Elsevier BV]
日期:2023-05-02
卷期号:239: 120035-120035
被引量:13
标识
DOI:10.1016/j.watres.2023.120035
摘要
In situ chemical oxidation (ISCO) is widely used as an efficient remediation technology for groundwater pollution. However, quantitative studies of its reactive remediation process under coupled thermal desorption technology are scarce. Based on laboratory experiments and site remediation, the chemical oxidation remediation reaction process was quantified, and the apparent reaction equation of the ISCO process was constructed. And then, a numerical model coupled with Hydraulic-Thermal-Chemical (HTC) fields was built to quantitatively describe the remediation process of an actual contaminated site. The simulation results fit well with the site monitoring data, and the results indicated that thermal desorption strengthens the ISCO remediation effect. In addition, the HTC model is expanded to build a conceptual and numerical model of a coupled remediation system, including heating and remediation wells. The results showed that high-temperature conditions enhance the activity of remediation chemicals and increase the rate of remediation reaction to obtain a better remediation effect. The heating wells increase the regional temperature, accelerating the diffusion of pollutants and remediation chemicals, and promoting adequate contact and reaction. Based on this crucial mechanism, thermal desorption coupled with ISCO technology can significantly improve remediation efficiency, shorten the remediation cycle, and precisely control agent delivery with the help of numerical simulation to avoid secondary contamination.
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