Abstract
Abstract. In global hydrological models, groundwater (GW) is typically represented by a bucket-like linear groundwater reservoir. Reservoir models, however, (1) can only simulate GW discharge to surface water (SW) bodies but not recharge from SW to GW, (2) provide no information on the location of the GW table, and (3) assume that there is no GW flow among grid cells. This may lead, for example, to an underestimation of groundwater resources in semiarid areas where GW is often replenished by SW or to an underestimation of evapotranspiration where the GW table is close to the land surface. To overcome these limitations, it is necessary to replace the reservoir model in global hydrological models with a hydraulic head gradient-based GW flow model. We present G3M, a new global gradient-based GW model with a spatial resolution of 5′ (arcminutes), which is to be integrated into the 0.5∘ WaterGAP Global Hydrology Model (WGHM). The newly developed model framework enables in-memory coupling to WGHM while keeping overall runtime relatively low, which allows sensitivity analyses, calibration, and data assimilation. This paper presents the G3M concept and model design decisions that are specific to the large grid size required for a global-scale model. Model results under steady-state naturalized conditions, i.e., neglecting GW abstractions, are shown. Simulated hydraulic heads show better agreement to observations around the world compared to the model output of de Graaf et al. (2015). Locations of simulated SW recharge to GW are found, as is expected, in dry and mountainous regions but areal extent of SW recharge may be underestimated. Globally, GW discharge to rivers is by far the dominant flow component such that lateral GW flows only become a large fraction of total diffuse and focused recharge in the case of losing rivers, some mountainous areas, and some areas with very low GW recharge. A strong sensitivity of simulated hydraulic heads to the spatial resolution of the model and the related choice of the water table elevation of surface water bodies was found. We suggest to investigate how global-scale groundwater modeling at 5′ spatial resolution can benefit from more highly resolved land surface elevation data.
Highlights
Groundwater (GW) is the source of about 40 % of all human water abstractions (Döll et al, 2014) and is an essential source of water for freshwater biota in rivers, lakes, and wetlands
We present G3M, a new global gradient-based GW model with a spatial resolution of 5, which is to be integrated into the 0.5◦ WaterGAP Global Hydrology Model (WGHM)
We present the Global Gradient-based Groundwater Model (G3M), which is to be integrated into the global hydrological models (GHMs) WaterGAP 2 to improve estimation of flows between surface water (SW) and GW and implement capillary rise
Summary
Groundwater (GW) is the source of about 40 % of all human water abstractions (Döll et al, 2014) and is an essential source of water for freshwater biota in rivers, lakes, and wetlands. GW abstractions have led to lowered water tables and, in some regions, even GW depletion (Döll et al, 2014; Scanlon et al, 2012; Wada et al, 2012; Konikow, 2011). This has resulted in reduced base flows to rivers and wetlands (with negative impacts on water quality and freshwater ecosystems), land. An improved understanding of GW systems and their interactions with SW and soil is needed at the local and regional scale and at the global scale
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