Challenges in developing a global gradient-based groundwater model (G&amp;lt;sup&amp;gt;3&amp;lt;/sup&amp;gt;M v1.0) for the integration into a global hydrological model

Reinecke, Robert D.; Foglia, Laura; Mehl, Steffen; Trautmann, Tim; Cáceres, Denise; Döll, Petra

doi:10.5194/gmd-12-2401-2019

Cited by 55 publications

(71 citation statements)

References 42 publications

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“…The assessment of global groundwater resources has been the subject of multiple studies recently, including impacts of groundwater abstractions (Wada et al ) and climate change (Portmann et al ; Cuthbert et al ). Furthermore, global hydrological models (GHMs) started to replace their bucket‐like linear groundwater storage models with (hydraulic) head gradient‐based models to better represent the interaction between surface water and groundwater as well as lateral and vertical flows, including capillary rise (de Graaf et al , , ; Reinecke et al , ). Compared to established regional models, global groundwater models are a new endeavor for groundwater hydrologists that is mostly unexplored.…”

Section: Introductionmentioning

confidence: 99%

Importance of Spatial Resolution in Global Groundwater Modeling

et al. 2020

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Global-scale gradient-based groundwater models are a new endeavor for hydrologists who wish to improve global hydrological models (GHMs). In particular, the integration of such groundwater models into GHMs improves the simulation of water flows between surface water and groundwater and of capillary rise and thus evapotranspiration. Currently, these models are not able to simulate water table depth adequately over the entire globe. Unsatisfactory model performance compared to well observations suggests that a higher spatial resolution is required to better represent the high spatial variability of land surface and groundwater elevations. In this study, we use New Zealand as a testbed and analyze the impacts of spatial resolution on the results of global groundwater models. Steady-state hydraulic heads simulated by two versions of the global groundwater model G 3 M, at spatial resolutions of 5 arc-minutes (9 km) and 30 arc-seconds (900 m), are compared with observations from the Canterbury region. The output of three other groundwater models with different spatial resolutions is analyzed as well. Considering the spatial distribution of residuals, general patterns of unsatisfactory model performance remain at the higher resolutions, suggesting that an increase in model resolution alone does not fix problems such as the systematic overestimation of hydraulic head. We conclude that (1) a new understanding of how low-resolution global groundwater models can be evaluated is required, and (2) merely increasing the spatial resolution of global-scale groundwater models will not improve the simulation of the global freshwater system.

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Section: Introductionmentioning

confidence: 99%

Importance of Spatial Resolution in Global Groundwater Modeling

et al. 2020

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“…Range of parameter multipliers used in the Morris experiments. Each parameter multiplier is sampled in log space (log 10 (Multiplier)) with sampling based on Campolongo et al (2007) and optimized with Ruano et al (2012).…”

Section: Global Hydrological Response Unitsmentioning

confidence: 99%

“…For 7 parameters (without the ocean boundary) and 6 GHRUs we get a total number of parameters k = 42 + 1, where +1 stands for the ocean boundary, which is not varied by GHRU, resulting in 1848 simulations. Elementary effects are based on an initial random sampling of 10 000 trajectories using Campolongo et al (2007) and then reduced by assuming 42 (number of parameters times GHRUs without ocean boundary) so-called optimized trajectories following Ruano et al (2012). Only random sampling might result in nonoptimal coverage of the input space; thus the initial random trajectories are used to select only those that maximize the dispersion in the input space.…”

Section: Experiments Configurationmentioning

confidence: 99%

“…Only random sampling might result in nonoptimal coverage of the input space; thus the initial random trajectories are used to select only those that maximize the dispersion in the input space. This optimal set of trajectories is approximated with a reasonable computational demand using the methodology developed by Ruano et al (2012). The experiment resulted in 1848 simulations with an overall runtime of 2 months on a machine with 20 computational cores (enabled hyper-threading) and 188 GB RAM.…”

Section: Experiments Configurationmentioning

confidence: 99%

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Spatially distributed sensitivity of simulated global groundwater heads and flows to hydraulic conductivity, groundwater recharge, and surface water body parameterization

Reinecke

Foglia

Mehl

et al. 2019

Hydrol. Earth Syst. Sci.

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In global hydrological models, groundwater storages and flows are generally simulated by linear reservoir models. Recently, the first global gradient-based groundwater models were developed in order to improve the representation of groundwater-surface-water interactions, capillary rise, lateral flows, and human water use impacts. However, the reliability of model outputs is limited by a lack of data and by uncertain model assumptions that are necessary due to the coarse spatial resolution. The impact of data quality is presented in this study by showing the sensitivity of a groundwater model to changes in the only available global hydraulic conductivity dataset. To better understand the sensitivity of model output to uncertain spatially distributed parameters, we present the first application of a global sensitivity method for a global-scale groundwater model using nearly 2000 steady-state model runs of the global gradientbased groundwater model G 3 M. By applying the Morris method in a novel domain decomposition approach that identifies global hydrological response units, spatially distributed parameter sensitivities are determined for a computationally expensive model. Results indicate that globally simulated hydraulic heads are equally sensitive to hydraulic conductivity, groundwater recharge, and surface water body elevation, though parameter sensitivities vary regionally. For large areas of the globe, rivers are simulated to be either losing or gaining, depending on the parameter combination, indicat-ing a high uncertainty in simulating the direction of flow between the two compartments. Mountainous and dry regions show a high variance in simulated head due to numerical instabilities of the model, limiting the reliability of computed sensitivities in these regions. This is likely caused by the uncertainty in surface water body elevation. We conclude that maps of spatially distributed sensitivities can help to understand the complex behavior of models that incorporate data with varying spatial uncertainties. The findings support the selection of possible calibration parameters and help to anticipate challenges for a transient coupling of the model.

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“…In particular, simulations of human water demands from different sectors such as agriculture, industry, and households could have a large impact on estimated hydrological storage (e.g., groundwater) and fluxes (e.g., discharge) (Alcamo et al, 2007;Wada et al, 2016). More efforts have gone into better groundwater representation in large-scale hydrological models to realistically simulate groundwater levels and surface-35 groundwater interactions (Pokhrel et al, 2015;Wada, 2016;Reinecke et al, 2019;de Graaf et al, 2015de Graaf et al, , 2017Decharme et al, 2019).…”

Section: Introduction 25mentioning

confidence: 99%

Development of the Community Water Model (CWatM v1.04) A high-resolution hydrological model for global and regional assessment of integrated water resources management

Burek¹,

Satoh²,

Kahil³

et al. 2019

Preprint

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We develop a new large-scale hydrological and water resources model, the Community Water Model (CWatM), which can simulate hydrology both globally and regionally at different resolutions from 30 arc min to 30 arc sec at daily time steps.CWatM is open-source in the Python programming environment and has a modular structure. It uses global, freely available data in the netCDF4 file format for reading, storage, and production of data in a compact way. CWatM includes general surface 15 and groundwater hydrological processes, but also takes into account human activities, such as water use and reservoir regulation, by calculating water demands, water use, and return flows. Reservoirs and lakes are included in the model scheme.CWatM is used in the framework of the Inter-Sectoral Impact Model Intercomparison Project (ISIMIP), which compares global model outputs. The flexible model structure allows dynamic interaction with hydro-economic and water quality models for the assessment and evaluation of water management options. Furthermore, the novelty of CWatM is its combination of state-of 20 the-art hydrological modeling, modular programming, an online user manual and automatic source code documentation, global and regional assessments at different spatial resolutions, and a potential community to add to, change, and expand the opensource project. CWatM also strives to build a community learning environment which is able to freely use an open-source hydrological model and flexible coupling possibilities to other sectoral models, such as energy and agriculture.PCR-GLOBWB Wada et al., 2014, Sutanudjaja et al., 2018, }, SAFRAN-ISBA-MODCOU (Habets et 30

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Challenges in developing a global gradient-based groundwater model (G<sup>3</sup>M v1.0) for the integration into a global hydrological model

Cited by 55 publications

References 42 publications

Importance of Spatial Resolution in Global Groundwater Modeling

Importance of Spatial Resolution in Global Groundwater Modeling

Spatially distributed sensitivity of simulated global groundwater heads and flows to hydraulic conductivity, groundwater recharge, and surface water body parameterization

Development of the Community Water Model (CWatM v1.04) A high-resolution hydrological model for global and regional assessment of integrated water resources management

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