Spatial and Temporal Variation in De Facto Wastewater Reuse in Drinking Water Systems across the U.S.A.

Rice, Jacelyn; Westerhoff, Paul

doi:10.1021/es5048057

Cited by 132 publications

(128 citation statements)

References 24 publications

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“…Regional‐scale multimedia models provide uniform exposure estimates for the surface‐water compartment based on regional or default general environmental fate properties rather than accounting for spatial variability (e.g., ChemCAN; Mackay et al ). More sophisticated screening‐level exposure models have been developed to better incorporate a spatial context to in‐stream exposure estimation, such as the following examples: GREAT‐ER model: Feijtel et al ; Koormann et al P h ATE model: Anderson et al ; Cunningham et al HydroROUT model: Lehner and Grill ScenAT model: Early approach detailed in Hodges et al ; CM Holmes, Waterborne Environmental, Leesburg, Virginia, USA, personal communication De facto wastewater reuse estimation: Rice et al …”

Section: Introductionmentioning

confidence: 99%

iSTREEM^®: An approach for broad-scale in-stream exposure assessment of “down-the-drain” chemicals

Kapo

DeLeo

Vamshi

et al. 2016

Integr Environ Assess Manag

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The "in-stream exposure model" iSTREEM(®) , a Web-based model made freely available to the public by the American Cleaning Institute, provides a means to estimate concentrations of "down-the-drain" chemicals in effluent, receiving waters, and drinking water intakes across national and regional scales under mean annual and low-flow conditions. We provide an overview of the evolution and utility of the iSTREEM model as a screening-level risk assessment tool relevant for down-the-drain products. The spatial nature of the model, integrating point locations of facilities along a hydrologic network, provides a powerful framework to assess environmental exposure and risk in a spatial context. A case study compared national distributions of modeled concentrations of the fragrance 1,3,4,6,7,8-Hexahydro-4,6,6,7,8,8,-hexamethylcyclopenta-γ-2-benzopyran (HHCB) and the insect repellent N,N-Diethyl-m-toluamide (DEET) to available monitoring data at comparable flow conditions. The iSTREEM low-flow model results yielded a conservative distribution of values, whereas the mean-flow model results more closely resembled the concentration distribution of monitoring data. We demonstrate how model results can be used to construct a conservative estimation of the distribution of chemical concentrations for effluents and streams leading to the derivation of a predicted environmental concentration (PEC) using the high end of the concentration distribution (e.g., 90th percentile). Data requirements, assumptions, and applications of iSTREEM are discussed in the context of other down-the-drain modeling approaches to enhance understanding of comparative advantages and uncertainties for prospective users interested in exposure modeling for ecological risk assessment. Integr Environ Assess Manag 2016;12:782-792. © 2016 SETAC.

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Section: Introductionmentioning

confidence: 99%

iSTREEM^®: An approach for broad-scale in-stream exposure assessment of “down-the-drain” chemicals

Kapo

DeLeo

Vamshi

et al. 2016

Integr Environ Assess Manag

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“…The study also provides a first step towards linking WWTP emissions to de facto reuse within the Netherlands. Indeed, this is one of very few studies to explore this problem [1,3,31], and to date, the only one that follows initial TWW emissions to the planar surface of agricultural fields. This is an important step in that it outlines a pathway by which TWW associated contaminants may spread through the surface water network and even to the subsurface.…”

Section: Model Successes Limitations Uncertaintiesmentioning

confidence: 99%

Following the Water: Characterising de facto Wastewater Reuse in Agriculture in the Netherlands

2019

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De facto (or indirect) wastewater reuse is the practice of extracting from surface water bodies which are impacted by treated wastewater (TWW) for anthropogenic use. The extent to which surface water bodies in the Netherlands are impacted by TWW is poorly understood, and the distribution of de facto reuse even more so. This study addresses these knowledge gaps, with a focus on reuse for agricultural irrigation. This is achieved via a novel application of the Water Framework Directive (WFD) Explorer water quality model, allowing for the distribution of different flow components-namely TWW and flow from transboundary rivers-to be discerned for the national surface water network. When paired with data on surface water extractions for irrigation, this identifies notable areas of de facto reuse. Results show that during dry conditions, TWW is a significant flow component in many surface water bodies, particularly in smaller streams located close to WWTPs. De facto reuse is indicated as widespread, with several key areas identified in which extractions are from impacted surface water bodies. This study represents a first attempt to directly link TWW emissions to agricultural irrigation, highlighting a mechanism by which wastewater-associated contaminants can propagate through the hydrological system.

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“…However, the majority of agricultural water reuse globally is the indirect or de facto reuse that occurs when wastewater is a dominant component of available surface water flows. Effluent from wastewater treatment plants can constitute a major portion of available surface water downstream of urban areas [13]. Consequently, alternate water reuse strategies such as industrial or domestic reuse or spatial redistribution of wastewater return flows, can have significant impacts on downstream farmers reliant on these urban wastewater return flows [14].…”

Section: Introductionmentioning

confidence: 99%

A global, spatially-explicit assessment of irrigated croplands influenced by urban wastewater flows

Thebo

Drechsel

Lambin

et al. 2017

Environ. Res. Lett.

174

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Spatial and Temporal Variation in De Facto Wastewater Reuse in Drinking Water Systems across the U.S.A.

Cited by 132 publications

References 24 publications

iSTREEM^®: An approach for broad-scale in-stream exposure assessment of “down-the-drain” chemicals

iSTREEM^®: An approach for broad-scale in-stream exposure assessment of “down-the-drain” chemicals

Following the Water: Characterising de facto Wastewater Reuse in Agriculture in the Netherlands

A global, spatially-explicit assessment of irrigated croplands influenced by urban wastewater flows

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Spatial and Temporal Variation in De Facto Wastewater Reuse in Drinking Water Systems across the U.S.A.

Cited by 132 publications

References 24 publications

iSTREEM®: An approach for broad-scale in-stream exposure assessment of “down-the-drain” chemicals

iSTREEM®: An approach for broad-scale in-stream exposure assessment of “down-the-drain” chemicals

Following the Water: Characterising de facto Wastewater Reuse in Agriculture in the Netherlands

A global, spatially-explicit assessment of irrigated croplands influenced by urban wastewater flows

Contact Info

Product

Resources

About

iSTREEM^®: An approach for broad-scale in-stream exposure assessment of “down-the-drain” chemicals

iSTREEM^®: An approach for broad-scale in-stream exposure assessment of “down-the-drain” chemicals