Evidence for Elevated Levels of Arsenic in Public Wells of Bangladesh Due To Improper Installation

Choudhury, Imtiaz Ahmed; Ahmed, Kazi Matin; Hasan, Mahmudul; Mozumder, Rajib Hassan; Knappett, Peter S.K.; Ellis, Tyler; Geen, Alexander van

doi:10.1111/gwat.12417

Cited by 17 publications

(17 citation statements)

References 18 publications

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“…The detection of modern tracers at some deep abstraction wells raises concerns about the vulnerability of these sites from shallow groundwater. The high salinity present at intermediate depths (Figure ) rules out vertical migration of shallow groundwater within the aquifer system and strongly suggests that these observations reflect short circuiting of shallow groundwater within pumping wells rather than vertical mixing within the local or regional aquifer system (I. Choudhury et al, ).…”

Section: Discussionmentioning

confidence: 97%

“…Regional‐scale modeling (Burgess et al, ; Hoque et al, ; Michael & Voss, , ) and field studies (McArthur et al, ; Mihajlov et al, ; Mukherjee et al, ; Ravenscroft et al, ) have explored the vulnerability of the deep groundwater in the coastal Bengal Aquifer System (BAS) to contamination yet key knowledge gaps remain. These include the relative importance of site‐specific, borehole‐ scale problems due to casing breaks at abstraction well sites (I. Choudhury et al, ) and aquifer‐scale vulnerabilities (Hoque et al, ) to contamination from shallow groundwater and the long‐term impacts of intensive pumping at depth (Khan et al, ; Knappett et al, ; Michael & Khan, ; Zahid et al, ). The presence of modern tracers (e.g., tritium and chlorofluorocarbons (CFCs)) in deeper groundwater systems (typically >150 m) has been attributed to deep pumping in the BAS and in many other aquifer systems globally (Jasechko et al, ; Lapworth et al, ; McMahon et al, ; Samborska et al, ) yet considerable uncertainty remains about the scale and nature of this pumping‐induced contamination.…”

Section: Introductionmentioning

confidence: 99%

“…These include the relative importance of site-specific, borehole-scale problems due to casing breaks at abstraction well sites (I. Choudhury et al, 2016) and aquifer-scale vulnerabilities (Hoque et al, 2017) to contamination from shallow groundwater and the long-term impacts of intensive pumping at depth Knappett et al, 2016;Zahid et al, 2014). The presence of modern tracers (e.g., tritium and chlorofluorocarbons (CFCs)) in deeper groundwater systems (typically >150 m) has been attributed to deep pumping in the BAS and in many other aquifer systems globally (Jasechko et al, 2017;Lapworth et al, 2015;McMahon et al, 2013;Samborska et al, 2013) yet considerable uncertainty remains about the scale and nature of this pumping-induced contamination.…”

Section: Introductionmentioning

confidence: 99%

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Security of Deep Groundwater in the Coastal Bengal Basin Revealed by Tracers

Lapworth

Zahid

Taylor

et al. 2018

Geophysical Research Letters

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Uncertainty persists regarding the vulnerability of deep groundwater across Asia's megadeltas. In the coastal Bengal Basin aquifer system, shallow groundwater (<100 m) commonly features high salinity or arsenic concentrations, and deep, better‐quality, groundwater supplies drinking water to >80 million people. Here we report new radiocarbon evidence from a network of nine dedicated, multilevel monitoring wells, which indicates residence times of between 103 and 104 years for groundwater at depths >150 m. Modern groundwater detected in some deep abstraction wells using anthropogenic tracers (SF6, CFCs) is attributed to short circuiting of shallow groundwater within wells. Age‐depth profiles and hydrochemical data in monitoring wells confirm the regional resilience of deep groundwater to ingress of shallow contaminated groundwater. Our results are consistent with high regional anisotropy in the aquifer and support continued use of deep groundwater though the potential for leakage of shallow contaminated groundwater in deep abstraction wells requires careful monitoring.

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Section: Discussionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Security of Deep Groundwater in the Coastal Bengal Basin Revealed by Tracers

Lapworth

Zahid

Taylor

et al. 2018

Geophysical Research Letters

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“…In this study, the transitional aquifer is referred to as “shallow” low‐As aquifer (<90 m bgl), whereas the deeper aquifers are split into “intermediate” (90–150 m bgl) and “deep” (>150 m bgl) categories. These definitions account for the drilling method used for well installations, as well as the government's Department of Public Health Engineering standard definition of wells deeper than 150 m as deep [ van Geen et al ., ; Choudhury et al ., ]. The shallow aquifer designates the low‐As aquifer that extends beneath the depth of peak As concentrations [ van Geen et al ., ] to the depth of ∼90 m bgl, within the reach of the traditional hand‐flapper installation method [ Ali , ; Horneman et al ., ].…”

Section: Introductionmentioning

confidence: 99%

Recharge of low‐arsenic aquifers tapped by community wells in Araihazar, Bangladesh, inferred from environmental isotopes

Mihajlov

Stute

Schlosser

et al. 2016

Water Resources Research

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More than 100,000 community wells have been installed in the 150–300 m depth range throughout Bangladesh over the past decade to provide low-arsenic drinking water (<10 μg/L As), but little is known about how aquifers tapped by these wells are recharged. Within a 25 km2 area of Bangladesh east of Dhaka, groundwater from 65 low-As wells in the 35–240 m depth range was sampled for tritium (3H), oxygen and hydrogen isotopes of water (18O/16O and 2H/1H), carbon isotope ratios in dissolved inorganic carbon (DIC, 14C/12C and 13C/12C), noble gases, and a suite of dissolved constituents, including major cations, anions, and trace elements. At shallow depths (<90 m), 24 out of 42 wells contain detectable 3H of up to 6 TU, indicating the presence of groundwater recharged within 60 years. Radiocarbon (14C) ages in DIC range from modern to 10 kyr. In the 90–240 m depth range, however, only 5 wells shallower than 150 m contain detectable 3H (<0.3 TU) and 14C ages of DIC cluster around 10 kyr. The radiogenic helium (4He) content in groundwater increases linearly across the entire range of 14C ages at a rate of 2.5×10−12 ccSTP 4He g−1 yr−1. Within the samples from depths >90 m, systematic relationships between 18O/16O, 2H/1H, 13C/12C and 14C/12C, and variations in noble gas temperatures, suggest that changes in monsoon intensity and vegetation cover occurred at the onset of the Holocene, when the sampled water was recharged. Thus, the deeper low-As aquifers remain relatively isolated from the shallow, high-As aquifer.

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“…Other maps were prepared using the QGIS software. However, some isolated pockets of As contamination exceeding 50 μg/L may be due to incorrect reporting of well depth or construction defects (Aggarwal, Basu, & Poreda, ; Choudhury et al, ; Ravenscroft et al, ; Stahl et al, ), and where such evidence was demonstrated, the record was omitted (Data S3), but where no contradictory evidence was obtained, anomalous records were retained. The reasons for incorrect depths are often non‐scientific, but the practical implication is that individual outliers should be treated with caution, and our approach was to look for verification by identifying patterns and consistency between independent data sources.…”

Section: Data Sources and Processingmentioning

confidence: 99%

Identifying multiple deep aquifers in the Bengal Basin: Implications for resource management

Ravenscroft¹,

McArthur

Rahman³

2018

Hydrological Processes

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In the Bengal Basin of Bangladesh and West Bengal (India), where arsenic (As) and salinity adversely affect groundwater in shallow aquifers (<150 m deep), consumers increasingly turn to "the deep aquifer" as a source of low-As and low-salinity water.We show that "the deep aquifer," which has traditionally been regarded as a single entity, can be divided into at least eight deep aquifer units each with distinctive chemical, isotopic, hydraulic, and piezometric characteristics. Except in the rapidly subsiding Sylhet Basin, the deep aquifers are largely As-safe (<50 μg/L and mostly <10 μg/L) but differ in terms of iron (Fe), manganese (Mn), salinity, stable isotopic composition, groundwater age, and in their piezometric response to pumping. We use isotopic data to identify recharge from five periods, of which two are quantitatively dominant: (a) from the Last Glacial Maximum, isotopically heavy water (δ 18 O >−3.5‰) with low As, Cl, and Fe concentrations occupies hydraulically trapped positions in the South-Central, Southeast, Southwest, and Madhupur aquifer units and (b) terminal Pleistocene to Early Holocene recharge of isotopically lighter water (δ 18 O <−3.5‰) that has high Fe and slightly elevated Cl concentrations and was recharged along palaeochannels that facilitated deep circulation up to the mid-Holocene. Piezometric responses to development change in style towards the coast. In the north, water levels at all depths tend to be coincident and transition through a seasonally divergent pattern to become parallel in the south with a near constant downward gradient. The delineation of the deep aquifer units provides a practical framework for the assessment and management of groundwater resources for water supply.

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Evidence for Elevated Levels of Arsenic in Public Wells of Bangladesh Due To Improper Installation

Cited by 17 publications

References 18 publications

Security of Deep Groundwater in the Coastal Bengal Basin Revealed by Tracers

Security of Deep Groundwater in the Coastal Bengal Basin Revealed by Tracers

Recharge of low‐arsenic aquifers tapped by community wells in Araihazar, Bangladesh, inferred from environmental isotopes

Identifying multiple deep aquifers in the Bengal Basin: Implications for resource management

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