Global-scale analysis of river flow alterations due to water withdrawals and reservoirs

Döll, Petra; Fiedler, K.; Zhang, Jing

doi:10.5194/hess-13-2413-2009

Cited by 457 publications

(407 citation statements)

References 35 publications

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“…This ensemble includes HTESSEL-CaMa (Balsamo et al, 2009), JULES Clark et al, 2011), LISFLOOD (van der Knijff et al, 2010), ORCHIDEE (Krinner et al, 2005;Ngo-Duc et al, 2007;d'Orgeval et al, 2008), SURFEX-TRIP (Alkama et al, 2010;Decharme et al, 2013), W3RA (van Dijk andWarren, 2010;van Dijk et al, 2014), WaterGAP3 (Flörke et al, 2013;Döll et al, 2009), PCR-GLOBWB (van Beek et al, 2011Wada et al, 2014), and SWBM (Orth et al, 2013). For consistency, we processed the model estimates in the same manner as our model simulations to directly compare modelled SWE and TWS to observations from GlobSnow and GRACE, respectively.…”

Section: Evaluation Of Model Performancementioning

confidence: 99%

Understanding terrestrial water storage variations in northern latitudes across scales

Trautmann

Koirala

Eicker

et al. 2018

Hydrol. Earth Syst. Sci.

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Abstract. The GRACE satellites provide signals of total terrestrial water storage (TWS) variations over large spatial domains at seasonal to inter-annual timescales. While the GRACE data have been extensively and successfully used to assess spatio-temporal changes in TWS, little effort has been made to quantify the relative contributions of snowpacks, soil moisture, and other components to the integrated TWS signal across northern latitudes, which is essential to gain a better insight into the underlying hydrological processes. Therefore, this study aims to assess which storage component dominates the spatio-temporal patterns of TWS variations in the humid regions of northern mid-to high latitudes.To do so, we constrained a rather parsimonious hydrological model with multiple state-of-the-art Earth observation products including GRACE TWS anomalies, estimates of snow water equivalent, evapotranspiration fluxes, and gridded runoff estimates. The optimized model demonstrates good agreement with observed hydrological spatio-temporal patterns and was used to assess the relative contributions of solid (snowpack) versus liquid (soil moisture, retained water) storage components to total TWS variations. In particular, we analysed whether the same storage component dominates TWS variations at seasonal and inter-annual temporal scales, and whether the dominating component is consistent across small to large spatial scales.Consistent with previous studies, we show that snow dynamics control seasonal TWS variations across all spatial scales in the northern mid-to high latitudes. In contrast, we find that inter-annual variations of TWS are dominated by liquid water storages at all spatial scales. The relative contribution of snow to inter-annual TWS variations, though, increases when the spatial domain over which the storages are averaged becomes larger. This is due to a stronger spatial coherence of snow dynamics that are mainly driven by temperature, as opposed to spatially more heterogeneous liquid water anomalies, that cancel out when averaged over a larger spatial domain. The findings first highlight the effectiveness of our model-data fusion approach that jointly interprets multiple Earth observation data streams with a simple model. Secondly, they reveal that the determinants of TWS variations in snow-affected northern latitudes are scale-dependent. In particular, they seem to be not merely driven by snow variability, but rather are determined by liquid water storages on interannual timescales. We conclude that inferred driving mechanisms of TWS cannot simply be transferred from one scale to another, which is of particular relevance for understanding the short-and long-term variability of water resources.

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Section: Evaluation Of Model Performancementioning

confidence: 99%

Understanding terrestrial water storage variations in northern latitudes across scales

Trautmann

Koirala

Eicker

et al. 2018

Hydrol. Earth Syst. Sci.

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show abstract

“…In the process, they have led to fragmented river systems with impacts on the hydrologic cycle [Graf, 1999]. Globally, water withdrawals and reservoirs have decreased annual discharge to the oceans by 2.7% with significant changes to the seasonal cycle of streamflow [Doll et al, 2009].…”

Section: Introductionmentioning

confidence: 99%

Debates—Perspectives on socio‐hydrology: Socio‐hydrologic modeling: Tradeoffs, hypothesis testing, and validation

Troy

Pavao-Zuckerman

Evans

2015

Water Resources Research

121

118

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Socio-hydrology focuses on studying the dynamics and co-evolution of coupled human and water systems. Recently, several new socio-hydrologic models have been published that explore these dynamics, and these models offer unique opportunities to better understand these coupled systems and to understand how water problems evolve similarly in different regions. These models also offer challenges, as decisions need to be made by the modeler on trade-offs between generality, precision, and realism. In addition, traditional hydrologic model validation techniques, such as evaluating simulated streamflow, are insufficient, and new techniques must be developed. As socio-hydrology progresses, these models offer a robust, invaluable tool to test hypotheses about the relationships between aspects of coupled human-water systems. They will allow us to explore multiple working hypotheses to greatly expand insights and understanding of coupled socio-hydrologic systems.

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“…Ensemble forecasting approach has not only been used to develop multi-model predictions, it is also a popular approach in treating uncertainties from different sources, including model inputs, ICs, and model parameters. To date, human activities are posing significant influence to terrestrial water cycle (Gerten et al, 2008) directly by water withdrawals, like crop irrigation (Tang et al, 2008;Leng et al, 2013), reservoir regulation (Döll et al, 2009) and groundwater pumping (Leng et al, 2014;Ferguson and Maxwell, 2012) and indirectly by altering the land cover (VanShaar et al, 2002). How to effectively parameterize such human interventions into land surface hydrological models is of critical importance for an improved knowledge of terrestrial hydrological variations under a changing environment.…”

Section: Uncertainties In Hydrological Forecastingmentioning

confidence: 99%

Hydrological monitoring and seasonal forecasting: Progress and perspectives

et al. 2016

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Hydrological monitoring and seasonal forecasting is an active research field because of its potential applications in hydrological risk assessment, preparedness and mitigation. In recent decades, developments in ground and satellite measurements have made the hydrometeorological information readily available, and advances in information technology have facilitated the data analysis in a real-time manner. New progress in climate research and modeling has enabled the prediction of seasonal climate with reasonable accuracy and increased resolution. These emerging techniques and advances have enabled more timely acquisition of accurate hydrological fluxes and status, and earlier warning of extreme hydrological events such as droughts and floods. This paper gives current state-of-the-art understanding of the uncertainties in hydrological monitoring and forecasting, reviews the efforts and progress in operational hydrological monitoring system assisted by observations from various sources and experimental seasonal hydrological forecasting, and briefly introduces the current monitoring and forecasting practices in China. The grand challenges and perspectives for the near future are also discussed, including acquiring and extracting reliable information for monitoring and forecasting, predicting realistic hydrological fluxes and states in the river basin being significantly altered by human activity, and filling the gap between numerical models and the end user. We highlight the importance of understanding the needs of the operational water management and the priority to transfer research knowledge to decision-makers.

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Global-scale analysis of river flow alterations due to water withdrawals and reservoirs

Cited by 457 publications

References 35 publications

Understanding terrestrial water storage variations in northern latitudes across scales

Understanding terrestrial water storage variations in northern latitudes across scales

Debates—Perspectives on socio‐hydrology: Socio‐hydrologic modeling: Tradeoffs, hypothesis testing, and validation

Hydrological monitoring and seasonal forecasting: Progress and perspectives

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