The influence of groundwater representation on hydrological simulation and its assessment using satellite‐based water storage variation

Huang, Zhongwei; Tang, Qiuhong; Lo, Min‐Hui; Liu, Xingcai; Lu, Hui; Zhang, Xuejun; Leng, Guoyong

doi:10.1002/hyp.13393

Cited by 18 publications

(10 citation statements)

References 59 publications

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“…Note that our approach is different from other previous studies. For instance, the developed approach by Niu et al (2007) and Huang et al (2019) extracts the baseflow from the aquifer, as a percentage of the storage or the water table depth using an exponential function. In our study, the flux of baseflow comes from the contribution of aquifer to the soil domain by an additional upward flux component.…”

Section: Discussionmentioning

confidence: 99%

“…There are two main classifications of groundwater coupling, namely, the empirical lumped GW models and the physically based distributed GW models (Tian et al, 2012). Regarding their dimension, this can be either a one‐dimensional (1‐D) model (e.g., Gedney & Cox, 2003; Maxwell & Miller, 2005; Yeh and Eltahir, 2005a; Niu et al, 2007; Huang et al, 2019), two‐dimensional (2‐D) model (e.g., Fan & Miguez‐Macho, 2011; Vergnes & Decharme, 2012) or 3‐D model (e.g., Gutowski Jr et al, 2002; Maxwell et al, 2011; Tian et al, 2012; York et al, 2002). In the 1‐D coupling, the soil domain is extrapolated for a few tens of meters.…”

Section: Introductionmentioning

confidence: 99%

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Towards the representation of groundwater in the Joint UK Land Environment Simulator

Batelis

Rahman

Kollet

et al. 2020

Hydrological Processes

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Groundwater is an important component of the hydrological cycle with significant interactions with soil hydrological processes. Recent studies have demonstrated that incorporating groundwater hydrology in land surface models (LSMs) considerably improves the prediction of the partitioning of water components (e.g., runoff and evapotranspiration) at the land surface. However, the Joint UK Land Environment Simulator (JULES), an LSM developed in the United Kingdom, does not yet have an explicit representation of groundwater. We propose an implementation of a simplified groundwater flow boundary parameterization (JULES‐GFB), which replaces the original free drainage assumption in the default model (JULES‐FD). We tested the two approaches under a controlled environment for various soil types using two synthetic experiments: (1) single‐column and (2) tilted‐V catchment, using a three‐dimensional (3‐D) hydrological model (ParFlow) as a benchmark for JULES’ performance. In addition, we applied our new JULES‐GFB model to a regional domain in the UK, where groundwater is the key element for runoff generation. In the single‐column infiltration experiment, JULES‐GFB showed improved soil moisture dynamics in comparison with JULES‐FD, for almost all soil types (except coarse soils) under a variety of initial water table depths. In the tilted‐V catchment experiment, JULES‐GFB successfully represented the dynamics and the magnitude of saturated and unsaturated storage against the benchmark. The lateral water flow produced by JULES‐GFB was about 50% of what was produced by the benchmark, while JULES‐FD completely ignores this process. In the regional domain application, the Kling‐Gupta efficiency (KGE) for the total runoff simulation showed an average improvement from 0.25 for JULES‐FD to 0.75 for JULES‐GFB. The mean bias of actual evapotranspiration relative to the Global Land Evaporation Amsterdam Model (GLEAM) product was improved from −0.22 to −0.01 mm day−1. Our new JULES‐GFB implementation provides an opportunity to better understand the interactions between the subsurface and land surface processes that are dominated by groundwater hydrology.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Towards the representation of groundwater in the Joint UK Land Environment Simulator

Batelis

Rahman

Kollet

et al. 2020

Hydrological Processes

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“…The groundwater model developed for this study can correctly capture these characteristic differences of groundwater and baseflow. Similarly, Huang et al (2019) showed that the use of a groundwater layer in a hydrological model can improve simulated surface discharge, particularly during low flows when baseflow contribution is high. A large-scale model including lateral flows offers the opportunity to disentangle both the diversity of groundwater responses and the differences of groundwater head and baseflow fluctuations, that is, the difference of groundwater drought and the groundwater's role in drought propagation.…”

Section: Water Resources Researchmentioning

confidence: 99%

Large‐Scale Assessment of Delayed Groundwater Responses to Drought

Hellwig

Graaf

Weiler

et al. 2020

Water Resources Research

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Groundwater is a vital resource for freshwater supply during extended droughts and also a key storage governing drought propagation through the hydrological cycle. Current drought monitoring lacks large‐scale estimates of groundwater droughts, but progress of country‐to‐global‐scale models in the last years suggests that they could now be valuable tools to study and monitor water availability during extended droughts. As a prerequisite the models would need to be able to depict the diverse groundwater response to precipitation well enough to distinguish spatial differences. Here we developed a high‐resolution transient groundwater model for Germany and tested its ability for representing the groundwater system dynamics with a focus on droughts. Validation of model results against streamflow‐separated baseflow and groundwater head observation confirmed the model's ability to generally represent the groundwater head dynamics over 40 years with lower model performance in mountainous regions where model resolution was too low to capture local valley aquifers. The precipitation accumulation time that has the highest correlation with groundwater anomalies increases with hydraulic conductivity and specific yield from few months in the Central German Uplands to several years in the porous aquifers of northern Germany. Corresponding to these differences, distinct meteorological drought types led to different simulated groundwater reactions across Germany. Given the importance of groundwater as a resource, large‐scale groundwater models are important tools for future studies on drought propagation as well as groundwater drought under climate change.

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“…冰川融水径流除了对下游河流、湖泊等水体径流和水位产生影响之外, 也可能增加土壤含水量、补给壤中流等影响地表产流过程, 从而改变下游河道径流, 这一影响过程往往更具有长期性 [67] . 黄河源区径流受冰川融水影响较大, 但汛期则以降水为主, 因此源区出口(唐乃亥站)汛期径流减少与源区降水减少导致的径流变化有较大关系 [68] ; 枯季地下水是径流的重要补给来源, 枯季径流的年际变化可能与冰雪融水有较大关系 [69] . 雅鲁藏布江从上游到下游受地下水补给和融水补给的比例逐渐增大, 近年来在全球变暖导致冰川退缩加剧的背景下, 上游融水径流变化对下游的影响可能更为显著和深刻 [67] .…”

Section: 流域冰川径流对气候变化的响应结果显示目前45%unclassified