同化能力是一个未得到充分利用的土壤和地下水污染治理概念,对场地关闭具有重要影响

IF 1.8 4区 环境科学与生态学 Q3 WATER RESOURCES
J.F. Devlin, Beth L. Parker, Andrea J.H. Rhoades, Robert J. Stuetzle, Shaily Mahendra, Joseph Scalia, Jens Blotevogel
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Since then, this idea has sparked remarkable remediation innovations where processes that occur naturally in the subsurface, including biodegradation, sorption, diffusion, abiotic reactions, and volatilization are enhanced by actions specifically designed to boost their role in lowering contaminant concentrations in groundwater.</p><p>By the 1990s, the age of “Natural Attenuation” (NA) was upon us, together with vigorous ethical and technical discussions aimed at understanding and explaining why the technology was not simply a euphemism for “do nothing.” Natural attenuation proponents held that natural processes tend to be protective of human and environmental health, are more cost- and resource effective than active remediation, and less risky by minimizing the aggressive movement of fluids in the subsurface. On the other hand, critics contended that NA amounted to a delay tactic aimed primarily at cost savings, with little or no risk reduction over reasonable time periods. Critically, since the end of the twentieth century, advancements in site characterization and monitoring tools have refined conceptual site models and established multiple lines of evidence that NA is associated with (1) well-constrained plume development and (2) diminished risk over space and time to an acceptable level without active remediation.</p><p>As NA gained acceptance, its adoption at sites became primarily dependent on evidence of biologically driven contaminant transformation as the primary attenuation mechanism. In the process, other important and effective processes, including the collective physical, geochemical, and hydrogeologic influences that can govern or complement contaminant mitigation were often overshadowed or completely overlooked. We know that chemical and physical mechanisms can play primary roles in reducing contaminant concentrations. This includes reactions with iron or manganese oxides, hydrolysis, sorption, diffusion, and dispersion, volatilization, and other mechanisms that lower a specified mass of contaminant, or contaminant mixture, in the subsurface. These processes can be influenced by, and feedback to, the biological activity in aquifers; the interconnectedness of biology, chemistry, and flow are better appreciated now than ever in the past. It is therefore intellectually, technologically, and economically wasteful to disregard any part of this compilation of processes when dealing with aquifer restoration. To improve site management and closure efforts, we need process-based conceptual site models that account for <i>all</i> the processes occurring in a groundwater system. Herein, we contend this can be realized by extending the current NA framework and giving proper recognition to a well-known but under-utilized concept: assimilative capacity (AC).</p><p>The idea of AC is decades old (e.g., Falk, <span>1963</span>). Depending on the literature consulted, the usage of the term varies somewhat, but generally alludes to the ability (by any mechanism) of an environmental system to transform or sequester various materials without deleterious effects to the system itself. Most often, AC has been associated with surface water resources (e.g., rivers and wetlands) and atmospheric studies (e.g., greenhouse gases). AC has also been integral in our approach to disposal of wastes (e.g., wastewater treatment effluents, septic systems and land application of biosolids). About 25 years ago the term was discussed in the context of sustainability and the need to avoid exceeding the AC of natural systems. By doing so, our growing and technologically advanced society could coexist with ecosystem services indefinitely (Cairns Jr <span>1999</span>).</p><p>In the specific context of groundwater systems literature, AC has been used since at least the 1970s (e.g., Willis <span>1976</span>), in arguably vague terms, with little hydrogeological context. Furthermore, following the rationale for NA, these discussions of AC appear to have emphasized intrinsic <i>processes</i> within a flow system rather than specific <i>quantities</i>, as suggested by the term “capacity.” This tendency has blurred the lines between NA and AC. <i>Going forward, it may be useful to make a clear distinction between AC and NA by defining AC as the mass of contaminant(s) that can be transformed or sequestered by a volume of subsurface over a specified period of time</i>, via <i>the chemical and physical mechanisms mentioned previously</i>. This definition frees hydrogeologists and engineers to design aquifer restoration programs and risk reduction projects that take full advantage of all nature's mechanisms for improving groundwater quality. Moreover, this definition applies to all hydrogeologic settings; it is relevant to cases involving small receptors and large plumes in quasi-steady state with no apparent migration. It is relevant to aquifers and aquitards. In the latter case, the concept of AC may be especially relevant because aquitards may be diffusion-controlled environments where time scales are extended and reactivity enhanced. High-resolution aquitard characterization techniques can provide accurate assessment of ‘assimilation’ rates simply through the analysis of concentration profiles (diffusion halos).</p><p>As alluded to previously, a major issue facing the application of the AC concept, extending the scope of NA, lies in our ability to characterize the subsurface for its capacity to “assimilate.” In diffusion-controlled settings, concentration profiles may be sufficient to accomplish this task. But, in many cases, even open and dynamic aquifers can be characterized for AC with confidence, using high-definition characterization tools and in situ flux characterization technologies. With these recent developments in tools, and a growing appreciation of conceptual site model development, we should now be able to shed light on the complete nature of the complex, and interwoven processes affecting contaminant transport and fate over space and time. For example, the familiar transect approach for assessing contaminant losses from groundwater within an aquifer volume is easily adapted using the new tools. In principle, measurement of contaminant discharges (or fluxes) at two bounding transects, upgradient and downgradient of the test volume, provide the data needed for the AC of that volume to be estimated in situ.</p><p>Another potentially fruitful application of AC is in documenting contaminant behavior at sites that have undergone NA or active remediation and are now exhibiting low but persistent concentrations of contaminants. Back-diffusion from low-permeability strata is thought to be a common source of such long-term dilute plumes. NA (as biodegradation) may be difficult to prove in such settings, since the aquifers may have returned to an oligotrophic state in which ambient microbial activity is no longer sufficient to drive contaminant concentrations to regulatory limits. A resulting lack of understanding and confidence that risk is under control will likely delay site closure, sometimes unnecessarily. On the other hand, other processes included in the AC concept may act to fill the gap, and be protective of aquifers to concentrations below safe thresholds. This could open the future to specific benefits including improved risk assessment, enhanced future land use, superior site-specific remediation standards, refined monitoring strategies, and successful technology adoption.</p><p>In summary, AC may be the concept of greatest relevance in thoughtful site closure decision making. AC is central to extending natural attenuation processes beyond those that have come to dominate NA thinking and be more versatile for distinct hydrogeologic and contaminant types. The recent high-definition characterization technologies and increasing emphasis on process-based site conceptual models are giving site management strategies more potency than ever before. The time has come for our body of groundwater research to seek to standardize the quantification of AC through the use of process-based site conceptual models developed using modern characterization and monitoring tools. As such, regulatory frameworks can be shaped by a more informed understanding of hydrogeologic principles to safeguard human health and the environment.</p>","PeriodicalId":55081,"journal":{"name":"Ground Water Monitoring and Remediation","volume":"44 2","pages":"3-4"},"PeriodicalIF":1.8000,"publicationDate":"2024-04-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1111/gwmr.12650","citationCount":"0","resultStr":"{\"title\":\"Assimilative Capacity Is an Under-Utilized Concept for Regulating Soil and Groundwater Contamination with Important Implications for Site Closure\",\"authors\":\"J.F. Devlin,&nbsp;Beth L. Parker,&nbsp;Andrea J.H. Rhoades,&nbsp;Robert J. 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Since then, this idea has sparked remarkable remediation innovations where processes that occur naturally in the subsurface, including biodegradation, sorption, diffusion, abiotic reactions, and volatilization are enhanced by actions specifically designed to boost their role in lowering contaminant concentrations in groundwater.</p><p>By the 1990s, the age of “Natural Attenuation” (NA) was upon us, together with vigorous ethical and technical discussions aimed at understanding and explaining why the technology was not simply a euphemism for “do nothing.” Natural attenuation proponents held that natural processes tend to be protective of human and environmental health, are more cost- and resource effective than active remediation, and less risky by minimizing the aggressive movement of fluids in the subsurface. On the other hand, critics contended that NA amounted to a delay tactic aimed primarily at cost savings, with little or no risk reduction over reasonable time periods. Critically, since the end of the twentieth century, advancements in site characterization and monitoring tools have refined conceptual site models and established multiple lines of evidence that NA is associated with (1) well-constrained plume development and (2) diminished risk over space and time to an acceptable level without active remediation.</p><p>As NA gained acceptance, its adoption at sites became primarily dependent on evidence of biologically driven contaminant transformation as the primary attenuation mechanism. In the process, other important and effective processes, including the collective physical, geochemical, and hydrogeologic influences that can govern or complement contaminant mitigation were often overshadowed or completely overlooked. We know that chemical and physical mechanisms can play primary roles in reducing contaminant concentrations. This includes reactions with iron or manganese oxides, hydrolysis, sorption, diffusion, and dispersion, volatilization, and other mechanisms that lower a specified mass of contaminant, or contaminant mixture, in the subsurface. These processes can be influenced by, and feedback to, the biological activity in aquifers; the interconnectedness of biology, chemistry, and flow are better appreciated now than ever in the past. It is therefore intellectually, technologically, and economically wasteful to disregard any part of this compilation of processes when dealing with aquifer restoration. To improve site management and closure efforts, we need process-based conceptual site models that account for <i>all</i> the processes occurring in a groundwater system. Herein, we contend this can be realized by extending the current NA framework and giving proper recognition to a well-known but under-utilized concept: assimilative capacity (AC).</p><p>The idea of AC is decades old (e.g., Falk, <span>1963</span>). Depending on the literature consulted, the usage of the term varies somewhat, but generally alludes to the ability (by any mechanism) of an environmental system to transform or sequester various materials without deleterious effects to the system itself. Most often, AC has been associated with surface water resources (e.g., rivers and wetlands) and atmospheric studies (e.g., greenhouse gases). AC has also been integral in our approach to disposal of wastes (e.g., wastewater treatment effluents, septic systems and land application of biosolids). About 25 years ago the term was discussed in the context of sustainability and the need to avoid exceeding the AC of natural systems. By doing so, our growing and technologically advanced society could coexist with ecosystem services indefinitely (Cairns Jr <span>1999</span>).</p><p>In the specific context of groundwater systems literature, AC has been used since at least the 1970s (e.g., Willis <span>1976</span>), in arguably vague terms, with little hydrogeological context. Furthermore, following the rationale for NA, these discussions of AC appear to have emphasized intrinsic <i>processes</i> within a flow system rather than specific <i>quantities</i>, as suggested by the term “capacity.” This tendency has blurred the lines between NA and AC. <i>Going forward, it may be useful to make a clear distinction between AC and NA by defining AC as the mass of contaminant(s) that can be transformed or sequestered by a volume of subsurface over a specified period of time</i>, via <i>the chemical and physical mechanisms mentioned previously</i>. This definition frees hydrogeologists and engineers to design aquifer restoration programs and risk reduction projects that take full advantage of all nature's mechanisms for improving groundwater quality. Moreover, this definition applies to all hydrogeologic settings; it is relevant to cases involving small receptors and large plumes in quasi-steady state with no apparent migration. It is relevant to aquifers and aquitards. In the latter case, the concept of AC may be especially relevant because aquitards may be diffusion-controlled environments where time scales are extended and reactivity enhanced. High-resolution aquitard characterization techniques can provide accurate assessment of ‘assimilation’ rates simply through the analysis of concentration profiles (diffusion halos).</p><p>As alluded to previously, a major issue facing the application of the AC concept, extending the scope of NA, lies in our ability to characterize the subsurface for its capacity to “assimilate.” In diffusion-controlled settings, concentration profiles may be sufficient to accomplish this task. But, in many cases, even open and dynamic aquifers can be characterized for AC with confidence, using high-definition characterization tools and in situ flux characterization technologies. With these recent developments in tools, and a growing appreciation of conceptual site model development, we should now be able to shed light on the complete nature of the complex, and interwoven processes affecting contaminant transport and fate over space and time. 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引用次数: 0

摘要

此外,这一定义适用于所有水文地质环境;它适用于涉及小型受体和处于准稳态且无明显迁移的大型羽流的情况。它适用于含水层和含水层。在后一种情况下,AC 的概念可能尤其相关,因为含水层可能是扩散控制的环境,在这种环境中,时间尺度延长,反应性增强。高分辨率含水层特征描述技术只需通过分析浓度剖面(扩散晕),就能准确评估 "同化 "率。如前所述,应用 "同化 "概念、扩大 NA 范围所面临的一个主要问题,在于我们是否有能力描述地下的 "同化 "能力。在扩散控制的环境中,浓度分布图可能足以完成这项任务。但在许多情况下,即使是开放的动态含水层,也可以利用高清表征工具和原位通量表征技术,可靠地表征其 "同化 "能力。随着这些工具的最新发展,以及对现场概念模型开发的日益重视,我们现在应该能够揭示影响污染物在空间和时间上迁移和归宿的复杂、交织过程的全部性质。例如,我们熟悉的横断面方法可用于评估含水层容积内地下水的污染物流失情况,而新工具则很容易对这种方法进行调整。原则上,在测试容积的上游和下游的两个边界横断面测量污染物排放(或通量),就可以为原位估算该容积的 AC 提供所需的数据。AC 的另一个潜在富有成效的应用是记录经过 NA 或积极修复、目前污染物浓度较低但持续存在的地点的污染物行为。低渗透性地层的反向扩散被认为是这种长期稀释羽流的常见来源。在这种情况下,NA(如生物降解)可能难以证明,因为含水层可能已经恢复到低营养状态,在这种状态下,环境中的微生物活动已不足以使污染物浓度达到监管限值。因此,如果对风险已得到控制缺乏了解和信心,很可能会延误场地的关闭,有时甚至是不必要的。另一方面,AC 概念中包含的其他过程可能会填补这一空白,并对含水层起到保护作用,使其浓度低于安全阈值。总之,在深思熟虑的场地关闭决策中,AC 可能是最相关的概念。自然衰减是扩展自然衰减过程的核心,它超越了主导自然衰减思想的自然衰减过程,对不同的水文地质和污染物类型具有更广泛的用途。最近的高清特征描述技术以及对基于过程的场地概念模型的日益重视,使场地管理策略比以往任何时候都更具效力。现在是时候了,我们的地下水研究机构应通过使用利用现代特征描述和监测工具开发的基于过程的现场概念模型,寻求将 AC 量化标准化。这样,就可以通过对水文地质原理的更深入了解来制定监管框架,从而保护人类健康和环境。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Assimilative Capacity Is an Under-Utilized Concept for Regulating Soil and Groundwater Contamination with Important Implications for Site Closure

The beginning of modern in situ subsurface cleanup arguably began in the early 1970s with the application of hydrogen peroxide to shallow aquifers to drive gasoline spill remediation, in what became known as the Raymond method (Committee on In Situ Bioremediation 1993). Since then, this idea has sparked remarkable remediation innovations where processes that occur naturally in the subsurface, including biodegradation, sorption, diffusion, abiotic reactions, and volatilization are enhanced by actions specifically designed to boost their role in lowering contaminant concentrations in groundwater.

By the 1990s, the age of “Natural Attenuation” (NA) was upon us, together with vigorous ethical and technical discussions aimed at understanding and explaining why the technology was not simply a euphemism for “do nothing.” Natural attenuation proponents held that natural processes tend to be protective of human and environmental health, are more cost- and resource effective than active remediation, and less risky by minimizing the aggressive movement of fluids in the subsurface. On the other hand, critics contended that NA amounted to a delay tactic aimed primarily at cost savings, with little or no risk reduction over reasonable time periods. Critically, since the end of the twentieth century, advancements in site characterization and monitoring tools have refined conceptual site models and established multiple lines of evidence that NA is associated with (1) well-constrained plume development and (2) diminished risk over space and time to an acceptable level without active remediation.

As NA gained acceptance, its adoption at sites became primarily dependent on evidence of biologically driven contaminant transformation as the primary attenuation mechanism. In the process, other important and effective processes, including the collective physical, geochemical, and hydrogeologic influences that can govern or complement contaminant mitigation were often overshadowed or completely overlooked. We know that chemical and physical mechanisms can play primary roles in reducing contaminant concentrations. This includes reactions with iron or manganese oxides, hydrolysis, sorption, diffusion, and dispersion, volatilization, and other mechanisms that lower a specified mass of contaminant, or contaminant mixture, in the subsurface. These processes can be influenced by, and feedback to, the biological activity in aquifers; the interconnectedness of biology, chemistry, and flow are better appreciated now than ever in the past. It is therefore intellectually, technologically, and economically wasteful to disregard any part of this compilation of processes when dealing with aquifer restoration. To improve site management and closure efforts, we need process-based conceptual site models that account for all the processes occurring in a groundwater system. Herein, we contend this can be realized by extending the current NA framework and giving proper recognition to a well-known but under-utilized concept: assimilative capacity (AC).

The idea of AC is decades old (e.g., Falk, 1963). Depending on the literature consulted, the usage of the term varies somewhat, but generally alludes to the ability (by any mechanism) of an environmental system to transform or sequester various materials without deleterious effects to the system itself. Most often, AC has been associated with surface water resources (e.g., rivers and wetlands) and atmospheric studies (e.g., greenhouse gases). AC has also been integral in our approach to disposal of wastes (e.g., wastewater treatment effluents, septic systems and land application of biosolids). About 25 years ago the term was discussed in the context of sustainability and the need to avoid exceeding the AC of natural systems. By doing so, our growing and technologically advanced society could coexist with ecosystem services indefinitely (Cairns Jr 1999).

In the specific context of groundwater systems literature, AC has been used since at least the 1970s (e.g., Willis 1976), in arguably vague terms, with little hydrogeological context. Furthermore, following the rationale for NA, these discussions of AC appear to have emphasized intrinsic processes within a flow system rather than specific quantities, as suggested by the term “capacity.” This tendency has blurred the lines between NA and AC. Going forward, it may be useful to make a clear distinction between AC and NA by defining AC as the mass of contaminant(s) that can be transformed or sequestered by a volume of subsurface over a specified period of time, via the chemical and physical mechanisms mentioned previously. This definition frees hydrogeologists and engineers to design aquifer restoration programs and risk reduction projects that take full advantage of all nature's mechanisms for improving groundwater quality. Moreover, this definition applies to all hydrogeologic settings; it is relevant to cases involving small receptors and large plumes in quasi-steady state with no apparent migration. It is relevant to aquifers and aquitards. In the latter case, the concept of AC may be especially relevant because aquitards may be diffusion-controlled environments where time scales are extended and reactivity enhanced. High-resolution aquitard characterization techniques can provide accurate assessment of ‘assimilation’ rates simply through the analysis of concentration profiles (diffusion halos).

As alluded to previously, a major issue facing the application of the AC concept, extending the scope of NA, lies in our ability to characterize the subsurface for its capacity to “assimilate.” In diffusion-controlled settings, concentration profiles may be sufficient to accomplish this task. But, in many cases, even open and dynamic aquifers can be characterized for AC with confidence, using high-definition characterization tools and in situ flux characterization technologies. With these recent developments in tools, and a growing appreciation of conceptual site model development, we should now be able to shed light on the complete nature of the complex, and interwoven processes affecting contaminant transport and fate over space and time. For example, the familiar transect approach for assessing contaminant losses from groundwater within an aquifer volume is easily adapted using the new tools. In principle, measurement of contaminant discharges (or fluxes) at two bounding transects, upgradient and downgradient of the test volume, provide the data needed for the AC of that volume to be estimated in situ.

Another potentially fruitful application of AC is in documenting contaminant behavior at sites that have undergone NA or active remediation and are now exhibiting low but persistent concentrations of contaminants. Back-diffusion from low-permeability strata is thought to be a common source of such long-term dilute plumes. NA (as biodegradation) may be difficult to prove in such settings, since the aquifers may have returned to an oligotrophic state in which ambient microbial activity is no longer sufficient to drive contaminant concentrations to regulatory limits. A resulting lack of understanding and confidence that risk is under control will likely delay site closure, sometimes unnecessarily. On the other hand, other processes included in the AC concept may act to fill the gap, and be protective of aquifers to concentrations below safe thresholds. This could open the future to specific benefits including improved risk assessment, enhanced future land use, superior site-specific remediation standards, refined monitoring strategies, and successful technology adoption.

In summary, AC may be the concept of greatest relevance in thoughtful site closure decision making. AC is central to extending natural attenuation processes beyond those that have come to dominate NA thinking and be more versatile for distinct hydrogeologic and contaminant types. The recent high-definition characterization technologies and increasing emphasis on process-based site conceptual models are giving site management strategies more potency than ever before. The time has come for our body of groundwater research to seek to standardize the quantification of AC through the use of process-based site conceptual models developed using modern characterization and monitoring tools. As such, regulatory frameworks can be shaped by a more informed understanding of hydrogeologic principles to safeguard human health and the environment.

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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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