Anna Störiko, Albert J. Valocchi, Charles Werth, Charles E. Schaefer
{"title":"Predicting Abiotic TCE Transformation Rate Constants—A Bayesian Hierarchical Approach","authors":"Anna Störiko, Albert J. Valocchi, Charles Werth, Charles E. Schaefer","doi":"10.1111/gwmr.12667","DOIUrl":null,"url":null,"abstract":"<p>Fe(II) minerals can mediate the abiotic reduction of trichloroethylene (TCE), a widespread groundwater contaminant. If reaction rates are sufficiently fast for natural attenuation, the process holds potential for mitigating TCE pollution in groundwater. To assess the variability of abiotic TCE reduction rate constants, we collected pseudo-first-order rate constants for natural sediments and rocks from the literature, as well as intrinsic (surface-area-normalized) rate constants of individual minerals. Using a Bayesian hierarchical modeling approach, we were able to differentiate the contributions of natural variability and experimental error to the total variance. Applying the model, we also predicted rate constants at new sites, revealing a considerable uncertainty of several orders of magnitude. We investigated whether incorporating additional information about sediment composition could reduce this uncertainty. We tested two sets of predictors: reactive mineral content (measured by X-ray diffraction) combined with surface areas and intrinsic rate constants, or the extractable Fe(II) content. Knowledge of the mineral composition only marginally reduced the uncertainty of predicted rate constants. We attribute the low information gain to the inability to measure the (reactive) surface areas of individual minerals in sediments or rocks, which are subject to environmental factors like aqueous geochemistry and redox potential. In contrast, knowing the Fe(II) content reduced the uncertainty about the first-order rate constant by nearly two orders of magnitude, because the relationship between Fe(II) content and rate constants is approximately log–log-linear. We demonstrate how our approach provides estimates for the range of cleanup times for a simple example of diffusion-controlled transport in a contaminated aquitard.</p>","PeriodicalId":55081,"journal":{"name":"Ground Water Monitoring and Remediation","volume":"44 4","pages":"67-79"},"PeriodicalIF":1.8000,"publicationDate":"2024-06-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1111/gwmr.12667","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Ground Water Monitoring and Remediation","FirstCategoryId":"93","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1111/gwmr.12667","RegionNum":4,"RegionCategory":"环境科学与生态学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"WATER RESOURCES","Score":null,"Total":0}
引用次数: 0
Abstract
Fe(II) minerals can mediate the abiotic reduction of trichloroethylene (TCE), a widespread groundwater contaminant. If reaction rates are sufficiently fast for natural attenuation, the process holds potential for mitigating TCE pollution in groundwater. To assess the variability of abiotic TCE reduction rate constants, we collected pseudo-first-order rate constants for natural sediments and rocks from the literature, as well as intrinsic (surface-area-normalized) rate constants of individual minerals. Using a Bayesian hierarchical modeling approach, we were able to differentiate the contributions of natural variability and experimental error to the total variance. Applying the model, we also predicted rate constants at new sites, revealing a considerable uncertainty of several orders of magnitude. We investigated whether incorporating additional information about sediment composition could reduce this uncertainty. We tested two sets of predictors: reactive mineral content (measured by X-ray diffraction) combined with surface areas and intrinsic rate constants, or the extractable Fe(II) content. Knowledge of the mineral composition only marginally reduced the uncertainty of predicted rate constants. We attribute the low information gain to the inability to measure the (reactive) surface areas of individual minerals in sediments or rocks, which are subject to environmental factors like aqueous geochemistry and redox potential. In contrast, knowing the Fe(II) content reduced the uncertainty about the first-order rate constant by nearly two orders of magnitude, because the relationship between Fe(II) content and rate constants is approximately log–log-linear. We demonstrate how our approach provides estimates for the range of cleanup times for a simple example of diffusion-controlled transport in a contaminated aquitard.
铁(II)矿物质可以介导广泛存在于地下水中的污染物三氯乙烯(TCE)的非生物还原。如果反应速度足够快,能够实现自然衰减,那么该过程就有可能减轻地下水中的三氯乙烯污染。为了评估 TCE 非生物还原速率常数的可变性,我们从文献中收集了天然沉积物和岩石的伪一阶速率常数,以及单个矿物的内在(表面积归一化)速率常数。利用贝叶斯分层建模方法,我们能够区分自然变异和实验误差对总变异的贡献。应用该模型,我们还对新地点的速率常数进行了预测,结果显示存在几个数量级的相当大的不确定性。我们研究了加入有关沉积物组成的额外信息是否能减少这种不确定性。我们测试了两组预测因子:活性矿物含量(通过 X 射线衍射测量)与表面积和内在速率常数相结合,或可提取的铁(II)含量。对矿物成分的了解只能略微降低预测速率常数的不确定性。我们将信息增益较低的原因归结为无法测量沉积物或岩石中单个矿物的(反应)表面积,而这些表面积会受到水地球化学和氧化还原电位等环境因素的影响。相比之下,了解铁(II)含量可将一阶速率常数的不确定性降低近两个数量级,因为铁(II)含量与速率常数之间的关系近似对数线性。我们演示了我们的方法如何为一个受污染含水层中扩散控制迁移的简单例子提供净化时间范围的估计值。
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.