Your search found 3 records
1 Fryar, A. E.; Macko, S. A.; Mullican, W. F.; Romanak, K. D.; Bennett, P. C. 2000. Nitrate reduction during ground-water recharge, Southern High Plains, Texas. Journal of Contaminant Hydrology, 40:335-363.
Groundwater ; Artificial recharge ; Aquifers ; Water reuse ; Wastewater ; Water quality ; Water pollution ; Irrigation water ; Water conservation ; Water table / USA / Texas / High Plains / Ogallala
(Location: IWMI-HQ Call no: P 5592 Record No: H027382)
2 Mukherjee, A.; Fryar, A. E.; Howell, P. D. 2007. Regional hydrostratigraphy and groundwater flow modeling in the arsenic-affected areas of the western Bengal basin, West Bengal, India. Hydrogeology Journal, 15:1397-1418. [doi: https://doi.org/10.1007/s10040-007-0208-7]
Groundwater ; Flow ; Aquifers ; Water quality ; Arsenic ; Hydrogeology ; Models / India / West Bengal / Western Bengal Basin
(Location: IWMI HQ Call no: e-copy only Record No: H042237)
(1.14 MB)
The first documented interpretation of the regional-scale hydrostratigraphy and groundwater flow is presented for a ~21,000-km2 area of the arsenic-affected districts of West Bengal [Murshidabad, Nadia, North 24 Parganas and South 24 Parganas (including Calcutta)], India. A hydrostratigraphic model demonstrates the presence of a continuous, semi-confined sand aquifer underlain by a thick clay aquitard. The aquifer thickens toward the east and south. In the south, discontinuous clay layers locally divide the near-surface aquifer into several deeper, laterally connected, confined aquifers. Eight 22-layer model scenarios of regional groundwater flow were developed based on the observed topography, seasonal conditions, and inferred hydrostratigraphy. The models suggest the existence of seasonally variable, regional, north–south flow across the basin prior to the onset of extensive pumping in the 1970s. Pumping has severely distorted the flow pattern, inducing high vertical hydraulic gradients across wide cones of depression. Pumping has also increased total recharge (including irrigational return flow), inflow from rivers, and sea water intrusion. Consequently, downward flow of arsenic contaminated shallow groundwater appears to have resulted in contamination of previously safe aquifers by a combination of mechanical mixing and changes in chemical equilibrium.
3 Jeelani, G.; Shah, R. A.; Deshpande, R. D.; Fryar, A. E.; Perrin, J.; Mukherjee, A. 2017. Distinguishing and estimating recharge to karst springs in snow and glacier dominated mountainous basins of the western Himalaya, India. Journal of Hydrology, 550:239-252. [doi: https://doi.org/10.1016/j.jhydrol.2017.05.001]
Water springs ; Recharge ; Karst ; Highlands ; Precipitation ; Snow cover ; Glaciers ; Snowmelt ; Flow discharge ; Temperature ; Rain ; Hydrogeology ; Hydrography ; Isotope analysis ; Elements ; Ions ; Chlorides ; Uncertainty / India / Western Himalaya / Liddar Basin / Kuthar Basin / Bringi Basin
(Location: IWMI HQ Call no: e-copy only Record No: H048190)
(4.76 MB)
Recharge assessment is a challenge in snow and glacier dominated Himalayan basins. Quantification of recharge to karst springs in these complex geological environments is important both for hydrologic understanding and for effective water resource management. We used spring hydrographs and environmental tracers (isotopes and solutes) to distinguish and estimate the sources of spring water and to identify the flow paths of the recharging waters in three mountainous basins of the western Himalaya. The karst springs are perennial with high discharge amplitudes. The results indicate that ambient temperature has a strong influence on the hydrological behavior of the springs. Although the spring flow is dominantly controlled by the melting of snow and/or glaciers, rain events produce sharp spikes in spring hydrographs. The facies patterns in springs within the Bringi basin (Ca-HCO3) and the Liddar basin (Ca-HCO3 and Ca-Mg-HCO3) suggest flow dominantly through limestone and dolomite. Higher concentrations of SO4 2 and Na+ in warm springs of the Kuthar basin indicate flow through carbonate, silicate and other rocks. The isotopic composition (d18O, d2 H) of precipitation, snowpacks, glacier melt and karst springs show wide variation both in space and time, and are strongly influenced by the basin relief and meteorology. The tracer-based two- and three-component mixing models suggest that the snowmelt dominantly contributes to the spring flow (55–96%), followed by glacier melt (5–36%) and rain (4–34%). Based on tracer tests with good recovery rates, springs are dominantly recharged through point sources rather than by diffuse infiltration. Changes in the timing, form, and amount of winter precipitation substantially affect the timing and magnitude of spring discharge during the rest of the year.
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