A hydrography upscaling method for scale invariant
parametrization of distributed hydrological models

Eilander, Dirk; Verseveld, Willem van; Yamazaki, Dai; Weerts, Albrecht; Winsemius, Hessel; Ward, Philip

doi:10.5194/hess-2020-582

Cited by 8 publications

(8 citation statements)

References 34 publications

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“…A priori values for reservoir demand, targets for full and minimum reservoir fractions are derived from available dataets. For more information, we refer to Imhoff et al (2020), Eilander et al (2021). The wflow_sbm source code is available under the MIT license from github (https://github.com/Deltares).…”

Section: Models Wflow_sbmmentioning

confidence: 99%

“…The third model is the distributed hydrological model wflow_sbm which parameterization is based on global datasets of physical catchment characteristics. The model is implemented at basin scale and (sub-)kilometer resolution (Imhoff et al, 2020;Eilander et al, 2021). Only for the simulations with LISFLOOD a bias-correction of the CORDEX data was applied.…”

Section: Introductionmentioning

confidence: 99%

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Estimating Regionalized Hydrological Impacts of Climate Change Over Europe by Performance-Based Weighting of CORDEX Projections

et al. 2021

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Ensemble projections of future changes in discharge over Europe show large variation. Several methods for performance-based weighting exist that have the potential to increase the robustness of the change signal. Here we use future projections of an ensemble of three hydrological models forced with climate datasets from the Coordinated Downscaling Experiment - European Domain (EURO-CORDEX). The experiment is set-up for nine river basins spread over Europe that hold different climate and catchment characteristics. We evaluate the ensemble consistency and apply two weighting approaches; the Climate model Weighting by Independence and Performance (ClimWIP) that focuses on meteorological variables and the Reliability Ensemble Averaging (REA) in our study applied to discharge statistics per basin. For basins with a strong climate signal, in Southern and Northern Europe, the consistency in the set of projections is large. For rivers in Central Europe the differences between models become more pronounced. Both weighting approaches assign high weights to single General Circulation Models (GCMs). The ClimWIP method results in ensemble mean weighted changes that differ only slightly from the non-weighted mean. The REA method influences the weighted mean more, but the weights highly vary from basin to basin. We see that high weights obtained through past good performance can provide deviating projections for the future. It is not apparent that the GCM signal dominates the overall change signal, i.e., there is no strong intra GCM consistency. However, both weighting methods favored projections from the same GCM.

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Section: Models Wflow_sbmmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Estimating Regionalized Hydrological Impacts of Climate Change Over Europe by Performance-Based Weighting of CORDEX Projections

et al. 2021

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“…First, we selected the region basin for the study using the MERIT Hydro elevation map (Yamazaki et al, 2019), which was upscaled to 30'' using the Iterative Hydrography Upscaling method (Eilander et al, 2020a), and subsequently selecting all upstream cells of the Krishna river outlet. Other routing maps, such as river slope and width, were obtained similarly (Eilander et al, 2020b).…”

Section: Model Setupmentioning

confidence: 99%

GEB v0.1: A large-scale agent-based socio-hydrological model – simulating 10 million individual farming households in a fully distributed hydrological model

Bruijn

Smilovic

Burek

et al. 2022

Preprint

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Abstract. Humans play a large role in the hydrological system; for example, by extracting large amounts of water for irrigation, often resulting in water stress and ecosystem degradation. By implementing large-scale adaptation measures, such as the construction of irrigation reservoirs, water stress and ecosystem degradation can be reduced. Yet we know that many decisions, such as the adoption of more effective irrigation techniques or changing crop types, are made at the farm level by a heterogeneous farmer population. While these decisions are often advantageous for an individual farmer or their community, detrimental effects are frequently experienced downstream. Therefore, to fully comprehend how the human-natural water system evolves over time and space, and to explore which interventions are suitable to reduce water stress, it is important to consider human behaviour and feedbacks to the hydrological system simultaneously at the local household and large basin scales. Therefore, we present the Geographical, Environmental and Behavioural model (GEB), a coupled agent-based hydrological model that simulates the behaviour and daily bi-directional interaction of up to ~10 million individual farm households with the hydrological system on a personal laptop. GEB is dynamically linked with the spatially distributed grid-based hydrological model CWatM at 30’’ resolution (< 1 km at the equator). Because many small-holder farmer fields are much smaller than 1×1 km, CWatM was specifically adapted to implement dynamically sized hydrological response units (HRUs) at the farm level, providing each agent with an independently operated hydrological environment. While the model could be applied globally, we explore its implementation in the heavily managed Krishna basin in India, which encompasses ~8 % of India’s land area and ~11.1 million farmers. Here, we show how six combinations of storylines with endogenous and exogenous drivers of adaptation affect both the hydrological system and the farmer population.

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“…The model includes snow, interception, root-zone, fast and slow storage components. Streamflow is routed through the upscaled river network at the model resolution (Eilander et al, 2020) with the kinematic wave approach. Similar implementations of that model were previously successfully used in a wide variety of environments (e.g.…”

Section: Wflow_flex-topo Hydrological Modelmentioning

confidence: 99%

The importance of ecosystem adaptation on hydrological model predictions in response to climate change

Bouaziz

Aalbers

Weerts

et al. 2021

Preprint

Self Cite

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Abstract. To predict future hydrological behavior in a changing world, often use is made of models calibrated on past observations, disregarding that hydrological systems, hence model parameters, will change as well. Yet, ecosystems likely adjust their root-zone storage capacity, which is the key parameter of any hydrological system, in response to climate change. In addition, other species might become dominant, both under natural and anthropogenic influence. In this study, we propose a top-down approach, which directly uses projected climate data to estimate how vegetation adapts its root-zone storage capacity at the catchment scale in response to changes in magnitude and seasonality of hydro-climatic variables. Additionally, the Budyko characteristics of different dominant ecosystems in sub-catchments are used to simulate the hydrological behavior of potential future land-use change, in a space-for-time exchange. We hypothesize that changes in the predicted hydrological response as a result of 2 K global warming are more pronounced when explicitly considering changes in the sub-surface system properties induced by vegetation adaptation to changing environmental conditions. We test our hypothesis in the Meuse basin in four scenarios designed to predict the hydrological response to 2 K global warming in comparison to current-day conditions using a process-based hydrological model with (a) a stationary system, i.e. no changes in the root-zone storage capacity of vegetation and historical land use, (b) an adapted root-zone storage capacity in response to a changing climate but with historical land use, and (c, d) an adapted root-zone storage capacity considering two hypothetical changes in land use from coniferous plantations/agriculture towards broadleaved forest and vice-versa. We found that the larger root-zone storage capacities (+34 %) in response to a more pronounced seasonality with drier summers under 2 K global warming strongly alter seasonal patterns of the hydrological response, with an overall increase in mean annual evaporation (+4 %), a decrease in recharge (−6 %) and a decrease in streamflow (−7 %), compared to predictions with a stationary system. By integrating a time-dynamic representation of changing vegetation properties in hydrological models, we make a potential step towards more reliable hydrological predictions under change.

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A hydrography upscaling method for scale invariant parametrization of distributed hydrological models

Cited by 8 publications

References 34 publications

Estimating Regionalized Hydrological Impacts of Climate Change Over Europe by Performance-Based Weighting of CORDEX Projections

Estimating Regionalized Hydrological Impacts of Climate Change Over Europe by Performance-Based Weighting of CORDEX Projections

GEB v0.1: A large-scale agent-based socio-hydrological model – simulating 10 million individual farming households in a fully distributed hydrological model

The importance of ecosystem adaptation on hydrological model predictions in response to climate change

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