Modeling of Complex, Multi-Component NAPL Remediation for Decision Support

IF 1.8 4区 环境科学与生态学 Q3 WATER RESOURCES Ground Water Monitoring and Remediation Pub Date : 2023-06-22 DOI:10.1111/gwmr.12594
Lloyd D. Stewart, Jennifer Nyman, Andres E. Prieto-Estrada, Julie C. Chambon, Mark A. Widdowson, Michael C. Kavanaugh
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Abstract

In situ remediation of nonaqueous phase liquid (NAPL)-impacted sites is difficult and costly. Even with enhancements (e.g., chemical and thermal) and partial NAPL recovery, mass transfer constraints associated with partitioning from residual NAPL typically control the depletion rate of sources and attainment of cleanup goals. Practical methodologies are needed to support strategic evaluation, planning, and implementation of cost-effective remedial approaches that are considered protective. A modeling system averaging over the NAPL-impacted saturated soil volume was developed and demonstrated at the former Williams Air Force Base. The system combines upscaled, physically based mass transfer coefficients for multi-component NAPL dissolution with theoretical enhancements specific to multiple remediation processes. Dissolution increases in the presence of aqueous phase reactions, according to first- or second-order kinetics, by increasing concentration gradients. Slow biological processes are considered first order in modeling natural attenuation and enhanced biological degradation. Fast reactions associated with chemical oxidation are considered second order. These enhancement models are equally applicable to numerical simulations of NAPL remediation. Pump and treat enhances dissolution in proportion to increases in the characteristic velocity associated with dissolution. The demonstration yielded realistic predictions, with greater certainty, for outcomes from of multiple technologies intended to reduce remedial timeframes and life cycle costs. The enhanced dissolution modeling provides a site-specific, quantitative assessment of changes in NAPL source discharge concentration and mass discharge over time for various remedial options that is equivalent to assessments from complex numerical transport models, given typical input data limitations.

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用于决策支持的复杂、多组件NAPL补救建模
非水相液体(NAPL)影响位点的原位修复是困难和昂贵的。即使进行了强化(如化学和热)和部分NAPL回收,与残余NAPL分配相关的传质约束通常也会控制源的消耗率和清洁目标的实现。需要实用的方法来支持被视为保护性的具有成本效益的补救方法的战略评估、规划和实施。在前威廉姆斯空军基地开发并演示了一个对NAPL影响的饱和土壤体积进行平均的建模系统。该系统将用于多组分NAPL溶解的放大的基于物理的传质系数与针对多种修复过程的理论增强相结合。根据一阶或二阶动力学,在水相反应存在的情况下,通过增加浓度梯度,溶解增加。在模拟自然衰减和增强的生物降解时,缓慢的生物过程被认为是第一级的。与化学氧化相关的快速反应被认为是二级反应。这些增强模型同样适用于NAPL修复的数值模拟。泵送和处理与溶解相关的特征速度的增加成比例地增强溶解。该演示对旨在减少补救时间框架和生命周期成本的多种技术的结果做出了更具确定性的现实预测。增强溶解模型为各种补救方案提供了一个特定地点的、定量的NAPL源排放浓度和质量排放随时间变化的评估,在给定典型输入数据限制的情况下,这相当于复杂数值传输模型的评估。
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来源期刊
CiteScore
3.30
自引率
10.50%
发文量
60
审稿时长
>36 weeks
期刊介绍: Since its inception in 1981, Groundwater Monitoring & Remediation® has been a resource for researchers and practitioners in the field. It is a quarterly journal that offers the best in application oriented, peer-reviewed papers together with insightful articles from the practitioner''s perspective. Each issue features papers containing cutting-edge information on treatment technology, columns by industry experts, news briefs, and equipment news. GWMR plays a unique role in advancing the practice of the groundwater monitoring and remediation field by providing forward-thinking research with practical solutions.
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