A comparative analysis of projected impacts of climate change on river runoff from global and catchment-scale hydrological models

Gosling, Simon N.; Taylor, Richard G.; Arnell, Nigel W.; Todd, Martin C.

doi:10.5194/hess-15-279-2011

Cited by 225 publications

(139 citation statements)

References 53 publications

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“…of the modeling chain is comparatively smaller (Crosbie et al, 2011;Kingston and Taylor, 2010;Gosling et al, 2011). However, according to Bastola et al (2011) "(.…”

Section: Introductionmentioning

confidence: 97%

What can we learn from long-term groundwater data to improve climate change impact studies?

Stoll

Franssen

Barthel

et al. 2011

Hydrol. Earth Syst. Sci.

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Abstract. Future risks for groundwater resources, due to global change are usually analyzed by driving hydrological models with the outputs of climate models. However, this model chain is subject to considerable uncertainties. Given the high uncertainties it is essential to identify the processes governing the groundwater dynamics, as these processes are likely to affect groundwater resources in the future, too. Information about the dominant mechanisms can be achieved by the analysis of long-term data, which are assumed to provide insight in the reaction of groundwater resources to changing conditions (weather, land use, water demand). Referring to this, a dataset of 30 long-term time series of precipitation dominated groundwater systems in northern Switzerland and southern Germany is collected. In order to receive additional information the analysis of the data is carried out together with hydrological model simulations. High spatio-temporal correlations, even over large distances could be detected and are assumed to be related to large-scale atmospheric circulation patterns. As a result it is suggested to prefer innovative weather-type-based downscaling methods to other stochastic downscaling approaches. In addition, with the help of a qualitative procedure to distinguish between meteorological and anthropogenic causes it was possible to identify processes which dominated the groundwater dynamics in the past. It could be shown that besides the meteorological conditions, land use changes, pumping activity and feedback mechanisms governed the groundwater dynamics. Based on these findings, recommendations to improve climate change impact studies are suggested.

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“…of the modeling chain is comparatively smaller (Crosbie et al, 2011;Kingston and Taylor, 2010;Gosling et al, 2011). However, according to Bastola et al (2011) "(.…”

Section: Introductionmentioning

confidence: 97%

What can we learn from long-term groundwater data to improve climate change impact studies?

Stoll

Franssen

Barthel

et al. 2011

Hydrol. Earth Syst. Sci.

View full text Add to dashboard Cite

show abstract

“…And the vast majority of the hydrological and HPP climate change impact studies come to the conclusion that climate modelling accounts for far more uncertainty than the local-scale hydro-hydraulic modelling (Schaefli et al, 2007;Bosshard et al, 2013;Gosling et al, 2011). This conclusion has, however, to be critically analyzed in light of the fact that very few studies confront hydrological models that are fundamentally different (Addor et al, 2014;Kobierska et al, 2013) or study a wide enough range of land use scenarios as e.g.…”

Section: From Uncertain Future Climate To Electricity Productionmentioning

confidence: 99%

Projecting hydropower production under future climates: a guide for decision‐makers and modelers to interpret and design climate change impact assessments

Schaefli

2015

WIREs Water

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Hydropower is a key energy source in almost all world regions, it fuels social and economic development, ensures electricity security and is a pillar for renewable electricity production. But hydropower and its environmental impacts are vulnerable to climate change. This discussion of model-based climate change impact assessments and underlying modelling assumptions will help decision makers and scientists analyzing existing studies and identifying the most urgent open questions. Rooted in hydrological uncertainty analysis, this discussion focuses on the importance of local factors and on modelling uncertainties for a critical view on our ability to project future hydropower production in different world regions.

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“…Gosling et al, 2011) this contribution is much smaller as compared to that from a GCM. To reduce biases and uncertainties of any individual GSM, a weighted ensemble mean is suggested to use for multimodel projections (Nohara et al, 2006).…”

Section: Introductionmentioning

confidence: 89%

Ability of a land surface model to predict climate induced changes in northern Russian river runoff during the 21st century

et al. 2015

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Abstract. The objective of the present study is application of the land surface model SWAP to project climate change impact on northern Russian river runoff up to 2100 using meteorological projections from the atmosphere-ocean global climate model INMCM4.0. The study was performed for the Northern Dvina River and the Kolyma River characterized by different climatic conditions. The ability of both models to reproduce the observed river runoff was investigated. To apply SWAP for hydrological projections, the robustness of the model was evaluated. The river runoff projections up to 2100 were calculated for two greenhouse gas emission scenarios: RCP8.5 and RCP4.5 prepared for the phase five of the Coupled Model Intercomparison Project (CMIP5). For each scenario, several runoff projections were obtained using different models (INMCM4.0 and SWAP) and different post-processing techniques for correcting biases in meteorological forcing data. Differences among the runoff projections obtained for the same emission scenario and the same period illustrate uncertainties resulted from application of different models and bias-correcting techniques.

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A comparative analysis of projected impacts of climate change on river runoff from global and catchment-scale hydrological models

Cited by 225 publications

References 53 publications

What can we learn from long-term groundwater data to improve climate change impact studies?

What can we learn from long-term groundwater data to improve climate change impact studies?

Projecting hydropower production under future climates: a guide for decision‐makers and modelers to interpret and design climate change impact assessments

Ability of a land surface model to predict climate induced changes in northern Russian river runoff during the 21st century

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