Depth Stratification Leads to Distinct Zones of Manganese and Arsenic Contaminated Groundwater

Ying, Samantha C.; Schaefer, Michael V.; Cock-Esteb, Alicea; Li, Jun; Fendorf, Scott

doi:10.1021/acs.est.7b01121

Cited by 69 publications

(69 citation statements)

References 44 publications

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“…Well depth characteristics were also influential predictor variables for our study (CaseDepth, rank = 14; DepthComp, rank = 27, Figure ). Our findings are consistent with and augment those by others that well depth (Ayotte et al, ; Ying et al, ), and depth below the water table (Tesoriero et al, ) are proxies for important As mobilization mechanisms. In our study, deeper depths generally increased the likelihood of predicted elevated As.…”

Section: Resultssupporting

confidence: 93%

“…Naturally occurring, geogenic arsenic (As) adversely affects drinking water quality of groundwater in geologically diverse aquifers in Europe, Africa, and North and South America, and particularly Southeast Asia (Amini et al, ; Bonsor et al, ; McArthur et al, ; Smedley & Kinniburgh, ; Wen et al, ). Within North America, naturally occurring As is widespread in groundwater throughout Late Quaternary glacial aquifers in the northern United States (Ayotte et al, ; Erickson, ; Root et al, ; Thomas, , ; Thomas et al, ; Warner, ; Warner & Ayotte, ; Welch et al, ; Ying et al, ). Groundwater supplies 50% of drinking water worldwide (Zekster & Everett, ) and 30% in the United States (U.S.) (U.S. Environmental Protection Agency, ), but compromised water quality from anthropogenic and natural contaminants can limit usage of groundwater as a drinking water source (Foster & Chilton, ; Nordstrom, ).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Predicting geogenic Arsenic in Drinking Water Wells in Glacial Aquifers, North‐Central USA: Accounting for Depth‐Dependent Features

Erickson

Elliott

Christenson

et al. 2018

Water Resources Research

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Chronic exposure to arsenic (As) via drinking groundwater is a human health concern worldwide. Probabilities of elevated geogenic As concentrations in groundwater were predicted in complex, glacial aquifers in Minnesota, north-central USA, a region that commonly has elevated As concentrations in well water. Maps of elevated As hazard were created for depths typical of drinking water supply and with well construction attributes common for domestic wells. Conventional variables describing aquifer properties and materials, position on the hydrologic landscape, and soil geochemistry were among the most influential for predicting the probability of elevated As. We also found that certain well construction attributes were influential in predicting As hazard. Smaller distances between the top of the well screen and overlying aquitard (proximity) and shorter well screen lengths were each associated with higher probabilities of elevated As. Influential predictor variables, which are either mapped across the region or are well construction attributes, are proxies in the model for measurable physical or geochemical causes of elevated As (e.g., redox condition, till or aquifer sediment chemistry, and water chemistry), which are not mapped across the region. Our setting shares some important characteristics with deltaic and other high-As aquifers in Southeast Asia: late Quaternary age, complex layering of coarse-and fine-grained materials, low-As sediment concentrations, and geochemical controls on As mobilization. Translating three-dimensional geologic and geochemical understanding of As mobility to quantifiable variables for modeling with powerful, flexible statistical tools could improve predictions and help identify safer groundwater supply options in the USA, Southeast Asia, and elsewhere.Plain Language Summary This study demonstrates that certain well construction attributes are influential in predicting arsenic (As) concentrations in drinking water wells. Smaller distances between the top of the well screen and overlying aquitard, and shorter well screen lengths, were each associated with higher probabilities of elevated As. Chronic exposure to As via drinking groundwater is a human health concern worldwide, and Minnesota, USA, commonly has elevated As concentrations in well water. This study describes a new, novel, and important finding from an As probability model: Controllable well construction choices (not just location or depth) influence As concentrations in drinking water from wells.

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Section: Resultssupporting

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Predicting geogenic Arsenic in Drinking Water Wells in Glacial Aquifers, North‐Central USA: Accounting for Depth‐Dependent Features

Erickson

Elliott

Christenson

et al. 2018

Water Resources Research

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“…Most at-risk populations are individuals with low body mass, those who consume high quantities of rice, and those who also ingest iAs via drinking water [7]. In an effort to devise approaches to minimize As entry into the human food chain, many studies have been conducted to understand how As is released from soils and sediments to water [8][9][10][11][12][13][14][15][16], where it can be taken up by rice roots. It has become clear that plant-availability of As in rice paddy agroecosystems is intimately tied to biogeochemical Fe and Mn cycling [17,18].…”

Section: Introductionmentioning

confidence: 99%

Si and Water Management Drives Changes in Fe and Mn Pools that Affect As Cycling and Uptake in Rice

Seyfferth

Limmer

2019

Soil Systems

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Arsenic availability to rice is tied to biogeochemical cycling of Fe and Mn in rice soils. Two strategies to minimize As uptake by rice—increasing Si and decreasing water—affect soil Fe and Mn pools. We synthesized data from several soil-based experiments with four rice cultivars across pot and field trials with manipulations of Si, water, or both. Increasing Si alters the mineral composition of Fe plaque more than decreasing water, with the former promoting relatively more ferrihydrite and less lepidocrocite. Nonflooded conditions decrease lepidocrocite but slightly increase goethite compared to flooded rice. Plaque As, which was a mixture of arsenite (15–40%) and arsenate (60–85%), was correlated positively with ferrihydrite and negatively with lepidocrocite and goethite. Plaque As was also positively correlated with F1 and F2 soil As, and F2 was correlated positively with porewater As, total grain As, and grain organic As (oAs). Grain inorganic As (iAs) was negatively correlated with oxalate-extractable Fe and Mn. Our data and multiple linear regression models suggest that under flooded conditions iAs is released by poorly crystalline Fe oxides to porewater mainly as iAs(III), which can either be taken up by the plant, adsorbed to Fe plaque, oxidized to iAs(V) or methylated to oAs. Increasing Si can promote more desorption of iAs(III) and promote more poorly-ordered phases in plaque and in bulk soil. The ultimate effectiveness of a Si amendment to decrease As uptake by rice depends upon it being able to increase exogenous Si relative to As in porewater after competitive adsorption/desorption processes. Our data further suggest that poorly crystalline Fe and Mn soil pools can retain inorganic As and decrease plant uptake, but these pools in bulk soil and plaque control grain organic As.

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“…Exposure to As, a known carcinogen, causes pulmonary, epidermal, liver, and kidney problems [19][20][21][22]. The fate of As in the subsurface is controlled, in part, by Mn oxides and aqueous Mn(II), due to the redox chemistry of As [23][24][25]. The mobile As III oxidation state is more toxic than the relatively immobile As V state [26].…”

Section: Introductionmentioning

confidence: 99%

“…Concentrations of As and Mn in these studies were as high as 1340 µg/L [28] and 4000 µg/L [27], respectively. An aggregation of many studies shows that Mn contamination (>400 µg/L) typically occurs in more shallow groundwater than As contamination (>10 µg/L) [25]. Furthermore, As depletion from solution can be predicted by sediment Mn oxide concentration [33].…”

Section: Introductionmentioning

confidence: 99%

Arsenite Depletion by Manganese Oxides: A Case Study on the Limitations of Observed First Order Rate Constants

Schacht

Ginder‐Vogel

2018

Soil Systems

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Arsenic (As) contamination of drinking water is a threat to global health. Manganese(III/IV) (Mn) oxides control As in groundwater by oxidizing more mobile As III to less mobile As V. Both As species sorb to the Mn oxide. The rates and mechanisms of this process are the subject of extensive research; however, as a group, study results are inconclusive and often contradictory. Here, the existing body of literature describing As III oxidation by Mn oxides is examined, and several potential reasons for inconsistent kinetic data are discussed. The oxidation of As III by Mn(III/IV) oxides is generally biphasic, with reported first order rate constants ranging seven orders of magnitude. Reanalysis of existing datasets from batch reactions of As III with δ-MnO 2 reveal that the first order rate constants reported for As depletion are time-dependent, and are not well described by pure kinetic rate models. This finding emphasizes the importance of mechanistic modeling that accounts for differences in reactivity between Mn III and Mn IV , and the sorption and desorption of As III , As V , and Mn II. A thorough understanding of the reaction is crucial to predicting As fate in groundwater and removing As via water treatment with Mn oxides, thus ensuring worldwide access to safe drinking water.

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Depth Stratification Leads to Distinct Zones of Manganese and Arsenic Contaminated Groundwater

Cited by 69 publications

References 44 publications

Predicting geogenic Arsenic in Drinking Water Wells in Glacial Aquifers, North‐Central USA: Accounting for Depth‐Dependent Features

Predicting geogenic Arsenic in Drinking Water Wells in Glacial Aquifers, North‐Central USA: Accounting for Depth‐Dependent Features

Si and Water Management Drives Changes in Fe and Mn Pools that Affect As Cycling and Uptake in Rice

Arsenite Depletion by Manganese Oxides: A Case Study on the Limitations of Observed First Order Rate Constants

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