Controlling geological and hydrogeological processes in an arsenic contaminated aquifer on the Red River flood plain, Vietnam
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Controlling geological and hydrogeological processes in an arsenic contaminated aquifer on the Red River flood plain, Vietnam. / Larsen, Flemming; Pham, Nhan Quy; Dang, Nhan Duc; Postma, Dieke; Jessen, Søren; Pham, Viet Hung; Nguyen, Thao Bach; Trieu, Huy Duc; Tran, Luu Thi; Nguyen, Hoan; Chambon, Julie; Nguyen, Hoan Van; Ha, Dang Hoang; Hue, Nguyen Thi; Duc, Mai Thanh; Refsgaard, Jens Christian.
I: Applied Geochemistry, Bind 23, Nr. 11, 2008, s. 3099-3115.Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt
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TY - JOUR
T1 - Controlling geological and hydrogeological processes in an arsenic contaminated aquifer on the Red River flood plain, Vietnam
AU - Larsen, Flemming
AU - Pham, Nhan Quy
AU - Dang, Nhan Duc
AU - Postma, Dieke
AU - Jessen, Søren
AU - Pham, Viet Hung
AU - Nguyen, Thao Bach
AU - Trieu, Huy Duc
AU - Tran, Luu Thi
AU - Nguyen, Hoan
AU - Chambon, Julie
AU - Nguyen, Hoan Van
AU - Ha, Dang Hoang
AU - Hue, Nguyen Thi
AU - Duc, Mai Thanh
AU - Refsgaard, Jens Christian
PY - 2008
Y1 - 2008
N2 - Geological and hydrogeological processes controlling recharge and the mobilization of As were investigated in a shallow Holocene aquifer on the Red River flood plain near Hanoi, Vietnam. The geology was investigated using surface resistivity methods, geophysical borehole logging, drilling of boreholes and installation of more than 200 piezometers. Recharge processes and surface-groundwater interaction were studied using (i) time-series of hydraulic head distribution in surface water and aquifers, (ii) the stable isotope composition of waters and (iii) numerical groundwater modeling. The Red River and two of its distributaries run through the field site and control the groundwater flow pattern. For most of the year, there is a regional groundwater flow towards the Red River. During the monsoon the Red River water stage rises up to 6 m and stalls the regional groundwater flow. The two distributaries recharge the aquifer from perched water tables in the dry season, whilst in the flooding period surface water enters the aquifer through highly permeable bank sediments. The result is a dynamic groundwater flow pattern with rapid fluctuations in the groundwater table. A transient numerical model of the groundwater flow yields an average recharge rate of 60-100 mm/a through the confining clay, and a total recharge of approximately 200 mm/a was estimated from 3H/3He dating of the shallow groundwater. Thus in the model area, recharge of surface water from the river distributaries and recharge through a confining clay is of the same magnitude, being on average around 100 mm/a. The thickness of the confining clay varies between 2 and 10 m, and affects the recharge rate and the transport of electron acceptors (O2, NO3- and SO42 -) into the aquifer. Where the clay layer is thin, an up to 2 m thick oxic zone develops in the shallow aquifer. In the oxic zone the As concentration is less than 1 μg/L but increases in the reduced zone below to 550 μg/L. In the Holocene aquifer, As is mobilized at a rate of around 14 μg/L/a. An As mass balance for the field site shows that around 1100 kg of As is annually leached from the Holocene sand and discharged into the Red River, corresponding to 0.01% of the total pool of As now present in the Holocene sand.
AB - Geological and hydrogeological processes controlling recharge and the mobilization of As were investigated in a shallow Holocene aquifer on the Red River flood plain near Hanoi, Vietnam. The geology was investigated using surface resistivity methods, geophysical borehole logging, drilling of boreholes and installation of more than 200 piezometers. Recharge processes and surface-groundwater interaction were studied using (i) time-series of hydraulic head distribution in surface water and aquifers, (ii) the stable isotope composition of waters and (iii) numerical groundwater modeling. The Red River and two of its distributaries run through the field site and control the groundwater flow pattern. For most of the year, there is a regional groundwater flow towards the Red River. During the monsoon the Red River water stage rises up to 6 m and stalls the regional groundwater flow. The two distributaries recharge the aquifer from perched water tables in the dry season, whilst in the flooding period surface water enters the aquifer through highly permeable bank sediments. The result is a dynamic groundwater flow pattern with rapid fluctuations in the groundwater table. A transient numerical model of the groundwater flow yields an average recharge rate of 60-100 mm/a through the confining clay, and a total recharge of approximately 200 mm/a was estimated from 3H/3He dating of the shallow groundwater. Thus in the model area, recharge of surface water from the river distributaries and recharge through a confining clay is of the same magnitude, being on average around 100 mm/a. The thickness of the confining clay varies between 2 and 10 m, and affects the recharge rate and the transport of electron acceptors (O2, NO3- and SO42 -) into the aquifer. Where the clay layer is thin, an up to 2 m thick oxic zone develops in the shallow aquifer. In the oxic zone the As concentration is less than 1 μg/L but increases in the reduced zone below to 550 μg/L. In the Holocene aquifer, As is mobilized at a rate of around 14 μg/L/a. An As mass balance for the field site shows that around 1100 kg of As is annually leached from the Holocene sand and discharged into the Red River, corresponding to 0.01% of the total pool of As now present in the Holocene sand.
U2 - 10.1016/j.apgeochem.2008.06.014
DO - 10.1016/j.apgeochem.2008.06.014
M3 - Journal article
AN - SCOPUS:54449097040
VL - 23
SP - 3099
EP - 3115
JO - Applied Geochemistry
JF - Applied Geochemistry
SN - 0883-2927
IS - 11
ER -
ID: 173937737