Hydrology Research (Dec 2020)
Integrating storage and spatial variability into shallow groundwater balances: moving towards water security in hard rock coastal areas
Abstract
In terrains with limited soil cover and groundwater storage, groundwater resource management is governed by the spatial nature of storage, recharge and distributed local extraction. Local soils act as important groundwater reservoirs for residents who have no other feasible water supply. A novel heuristic methodology is presented which accounts for the spatial distribution of storage and extraction, using existing topographical and geological databases in addition to well data to construct an applied conceptual groundwater model with assumed stratigraphy. The method uses a geographic information systems (GIS) environment and allows for modelling climate and land-use scenarios. Several scenarios were examined, demonstrating that average reservoir volumes meet demand but at the local levels depletion of reservoirs occurs. Groundwater abstraction in excess of 50% of the approximate freshwater storage was observed in the model, particularly near the coast. Soil-filled valleys may act as local hydraulic barriers by maintaining a higher pressure head as they are less susceptible to large-level fluctuations than the hard rock and may aid in preventing contamination from saline water provided no direct hydraulic connection is present. The method demonstrates the importance of a spatial approach in managing groundwater resources and could be used as a tool in increasing water security. HIGHLIGHTS A novel approach to a groundwater balance integrating limited storage was developed and applied to near coastal hard rock regions.; The surrogate method accounts for the spatial aspects of water extraction and storage at high-resolution and the temporal nature of groundwater recharge.; Results indicate that storage is a key factor for improving water security in coastal hard rock terrains with limited storage.; Parametric sensitivity analyses indicate that uncertainty in the storage parameter is highly spatially sensitive and dependent on the local geological conditions, in addition to likely being the most important factor in identifying sustainable groundwater extraction in hard rock coastal areas.; This novel approach could be used in groundwater resources management to identify vulnerable areas and allocate limited resources in decreasing corresponding parametric uncertainty.;
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