An integrated evaluation of bioenhanced in situ LNAPL dissolution

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-04-10 DOI:10.1016/j.jconhyd.2024.104338
Eric A. Seagren , David J. Hollander , David A. Stahl , Bruce E. Rittmann
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Abstract

Performance evaluation of in situ bioremediation processes in the field is difficult due to uncertainty created by matrix and contaminant heterogeneity, inaccessibility to direct observation, expense of sampling, and limitations of some measurements. The goal of this research was to develop a strategy for evaluating in situ bioremediation of light nonaqueous-phase liquid (LNAPL) contamination and demonstrating the occurrence of bioenhanced LNAPL dissolution by: (1) integrating a suite of analyses into a rational evaluation strategy; and (2) demonstrating the strategy's application in intermediate-scale flow-cell (ISFC) experiments simulating an aquifer contaminated with a pool of LNAPL (naphthalene dissolved in dodecane). Two ISFCs were operated to evaluate how the monitored parameters changed between a “no bioremediation” scenario and an “intrinsic in situ bioremediation” scenario. Key was incorporating different measures of microbial activity and contaminant degradation relevant to bioremediation: contaminant loss; consumption of electron acceptors; and changes in total alkalinity, pH, dissolved total inorganic carbon, carbon-stable isotopes, microorganisms, and intermediate metabolites. These measurements were integrated via mass-flux modeling and mass-balance analyses to document that in situ biodegradation of naphthalene was strongly accelerated in the “intrinsic in situ bioremediation” scenario versus “no bioremediation.” Furthermore, the integrated strategy provided consistent evidence of bioenhancement of LNAPL dissolution through intrinsic bioremediation by a factor of approximately 2 due to the biodegradation of the naphthalene near the pool/water interface.

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生物强化原位溶解 LNAPL 的综合评估
由于基质和污染物的异质性、无法直接观察、取样费用以及某些测量方法的局限性等因素造成的不确定性,很难对现场原位生物修复过程进行性能评估。本研究的目标是开发一种策略,用于评估轻质非水相液体(LNAPL)污染的原位生物修复,并通过以下方法证明生物增强 LNAPL 溶解的发生:(1) 将一系列分析整合为合理的评估策略;以及 (2) 在模拟受 LNAPL(溶解于十二烷中的萘)池污染的含水层的中间尺度流动池(ISFC)实验中演示该策略的应用。运行了两个 ISFC,以评估在 "无生物修复 "方案和 "固有原位生物修复 "方案之间监测参数的变化情况。关键是纳入与生物修复相关的微生物活动和污染物降解的不同测量指标:污染物流失;电子受体消耗;以及总碱度、pH 值、溶解无机碳总量、碳稳定同位素、微生物和中间代谢物的变化。通过质量流量建模和质量平衡分析,对这些测量结果进行了整合,以证明在 "固有原位生物修复 "与 "无生物修复 "的情况下,萘的原位生物降解速度大大加快。此外,综合战略还提供了一致的证据,证明由于池/水界面附近的萘发生了生物降解,通过固有生物修复,LNAPL 的生物溶解增强了约 2 倍。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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