Recent advances in anomalous transport models for predicting contaminants in natural groundwater systems

Diogo Bolster; Kevin R. Roche; Verónica L. Morales

doi:10.1016/j.coche.2019.09.006

Recent advances in anomalous transport models for predicting contaminants in natural groundwater systems

Diogo Bolster, Kevin R. Roche, Verónica L. Morales

Civil Engineering Department

Research output: Contribution to journal › Review article › peer-review

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Abstract

High degrees of spatial heterogeneity in hydrologic systems pose a major barrier for their protection and remediation. Dissolved and particulate contaminants are mixed and retained over timescales ranging from seconds to years due to their interactions with these structural heterogeneities. Over the last two decades, a new class of models has demonstrated its capacity to describe observed ‘anomalous transport’ behavior that is ubiquitous to nearly all flowing waters. The promise of these models lies in their potential for predicting transport using minimal parameters, while remaining faithful to the underlying complexity of the system. In this review, we highlight recent experimental studies that have improved our understanding of the structural controls of anomalous transport, as well as modeling studies that use these new insights to better predict contaminant fate.

Original language	English
Pages (from-to)	72-80
Number of pages	9
Journal	Current Opinion in Chemical Engineering
Volume	26
DOIs	https://doi.org/10.1016/j.coche.2019.09.006
State	Published - Dec 2019

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Civil and Environmental Engineering

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Roche, Kevin (2019) Recent Advances in Anomalous - PUB SelWrks.pdfFinal published version, 2.25 MBLicense: Unspecified

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title = "Recent advances in anomalous transport models for predicting contaminants in natural groundwater systems",

abstract = "High degrees of spatial heterogeneity in hydrologic systems pose a major barrier for their protection and remediation. Dissolved and particulate contaminants are mixed and retained over timescales ranging from seconds to years due to their interactions with these structural heterogeneities. Over the last two decades, a new class of models has demonstrated its capacity to describe observed {\textquoteleft}anomalous transport{\textquoteright} behavior that is ubiquitous to nearly all flowing waters. The promise of these models lies in their potential for predicting transport using minimal parameters, while remaining faithful to the underlying complexity of the system. In this review, we highlight recent experimental studies that have improved our understanding of the structural controls of anomalous transport, as well as modeling studies that use these new insights to better predict contaminant fate.",

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T1 - Recent advances in anomalous transport models for predicting contaminants in natural groundwater systems

AU - Bolster, Diogo

AU - Roche, Kevin R.

AU - Morales, Verónica L.

PY - 2019/12

Y1 - 2019/12

N2 - High degrees of spatial heterogeneity in hydrologic systems pose a major barrier for their protection and remediation. Dissolved and particulate contaminants are mixed and retained over timescales ranging from seconds to years due to their interactions with these structural heterogeneities. Over the last two decades, a new class of models has demonstrated its capacity to describe observed ‘anomalous transport’ behavior that is ubiquitous to nearly all flowing waters. The promise of these models lies in their potential for predicting transport using minimal parameters, while remaining faithful to the underlying complexity of the system. In this review, we highlight recent experimental studies that have improved our understanding of the structural controls of anomalous transport, as well as modeling studies that use these new insights to better predict contaminant fate.

AB - High degrees of spatial heterogeneity in hydrologic systems pose a major barrier for their protection and remediation. Dissolved and particulate contaminants are mixed and retained over timescales ranging from seconds to years due to their interactions with these structural heterogeneities. Over the last two decades, a new class of models has demonstrated its capacity to describe observed ‘anomalous transport’ behavior that is ubiquitous to nearly all flowing waters. The promise of these models lies in their potential for predicting transport using minimal parameters, while remaining faithful to the underlying complexity of the system. In this review, we highlight recent experimental studies that have improved our understanding of the structural controls of anomalous transport, as well as modeling studies that use these new insights to better predict contaminant fate.

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DO - 10.1016/j.coche.2019.09.006

M3 - Review article

AN - SCOPUS:85073609063

VL - 26

SP - 72

EP - 80

JO - Current Opinion in Chemical Engineering

JF - Current Opinion in Chemical Engineering

ER -

Recent advances in anomalous transport models for predicting contaminants in natural groundwater systems

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