Your search keyword '"Vanderkelen, Inne"' showing total 21 results

1. Attribution of global lake systems change to anthropogenic forcing

Author

Grant, Luke, Vanderkelen, Inne, Gudmundsson, Lukas, Tan, Zeli, Perroud, Marjorie, Stepanenko, Victor M., Debolskiy, Andrey V., Droppers, Bram, Janssen, Annette B. G., Woolway, R. Iestyn, Choulga, Margarita, Balsamo, Gianpaolo, Kirillin, Georgiy, Schewe, Jacob, Zhao, Fang, del Valle, Iliusi Vega, Golub, Malgorzata, Pierson, Don, Marcé, Rafael, Seneviratne, Sonia I., and Thiery, Wim

Published

2021

2. A Flexible Framework for Simulating the Water Balance of Lakes and Reservoirs From Local to Global Scales: mizuRoute‐Lake.

Author

Gharari, Shervan, Vanderkelen, Inne, Tefs, Andrew, Mizukami, Naoki, Kluzek, Erik, Stadnyk, Tricia, Lawrence, David, and Clark, Martyn P.

Subjects

RESERVOIRS, LAKES, HYDROLOGIC cycle, WATER supply, WATER management, WATERSHEDS, LAKE management

Abstract

Lakes and reservoirs are an integral part of the terrestrial water cycle. In this work, we present the implementation of different water balance models of lakes and reservoirs into mizuRoute, a vector‐based routing model, termed mizuRoute‐Lake. As the main advantage of mizuRoute‐Lake, users can choose between various parametric models implemented in mizuRoute‐Lake. So far, three parametric models of lake and reservoir water balance, namely Hanasaki, HYPE, and Döll are implemented in mizuRoute‐Lake. In general, the parametric models relate the outflow from lakes or reservoirs to the storage and various parameters including inflow, demand, volume of storage, etc. Additionally, this flexibility allows users to easily evaluate and compare the effect of various water balance models for a lake without needing to reconfigure the routing model or change the parameters of other lakes or reservoirs in the modeling domain. Users can also use existing data such as historical observations or water management models to specify the behavior of a selected number of lakes and reservoirs within the modeling domain using the data‐driven capability of mizuRoute‐Lake. We demonstrate the flexibility of mizuRoute‐Lake by presenting global, regional, and local scale applications. The development of mizuRoute‐Lake paves the way for better integration of water management models, locally measured, and remotely sensed data sets in the context of Earth system modeling. Plain Language Summary: Lakes and reservoirs impact the hydrological cycle. While there are many lake and reservoir models, a modeling framework typically encompasses a single selected lake and/or reservoir model representation. Including various lake discharge models in one model framework is useful for many applications of water resources. In this study, we present the implementation of various lake and reservoir water balance models in the mizuRoute‐Lake. mizuRoute‐Lake provides the flexibility to use and evaluate different lake and reservoir water balance models in river basins. Such flexibility can facilitate the integration with Earth system models, land surface models, water management models, and in situ or remote sensing observations. Additionally, it can help shed light on often neglected interactions and uncertainties in lake and reservoir models and their parameterizations within the hydrological cycle. Key Points: mizuRoute‐Lake offers the flexibility to select from multiple parametric models for lakes and reservoirs' water balanceUsers can leverage existing data, historical observations, water management models, and remotely sensed data, to specify lake behaviorThe versatility of mizuRoute‐Lake is demonstrated through its application at different scales, global to local [ABSTRACT FROM AUTHOR]

Published

2024

3. Bridging the gap: a new module for human water use in the Community Earth System Model version 2.2.1.

Author

Taranu, Sabin I., Lawrence, David M., Wada, Yoshihide, Tang, Ting, Kluzek, Erik, Rabin, Sam, Yao, Yi, Hertog, Steven J. De, Vanderkelen, Inne, and Thiery, Wim

Subjects

WATER use, WATER shortages, WATER management, WATER withdrawals, EARTH (Planet), SUPPLY & demand

Abstract

Water scarcity is often triggered by shifting climate patterns as well as rising water usage, yet state-of-the-art Earth system models typically do not represent human water demand. Here we present an enhancement to the Community Earth System Model (CESM) and its land (CLM) and river (MOSART) components by introducing sectoral water abstractions. The new module enables a better understanding of water demand and supply dynamics across various sectors, including domestic, livestock, thermoelectric, manufacturing, mining, and irrigation. The module conserves water by integrating abstractions from the land component with river component flows, and dynamically calculates daily water scarcity based on local demand and supply. Through land-only simulations spanning 1971–2010, we verify our model against known water scarcity hotspots, historical global water withdrawal trends, and regional variations in water use. Our findings reaffirm the role of irrigation in modulating local surface energy fluxes, while emphasizing the importance of including all sectors for water scarcity assessment capabilities. While the model captures global patterns, it also discerns regional nuances, expanding on the conventional focus on irrigation withdrawals in Earth system models (ESMs). Despite its advancements, the model's limitations, such as its exclusive focus on river water abstractions, highlight areas for potential future refinement. This research paves the way for a more holistic representation of human-water interactions in ESMs, aiming to inform sustainable water management decisions in an evolving global landscape. [ABSTRACT FROM AUTHOR]

Published

2024

4. A novel method for assessing climate change impacts in ecotron experiments

Author

Vanderkelen, Inne, Zscheischler, Jakob, Gudmundsson, Lukas, Keuler, Klaus, Rineau, Francois, Beenaerts, Natalie, Vangronsveld, Jaco, Vicca, Sara, and Thiery, Wim

Published

2020

5. Phenological shifts in lake stratification under climate change

Author

Woolway, R. Iestyn, Sharma, Sapna, Weyhenmeyer, Gesa A., Debolskiy, Andrey, Golub, Malgorzata, Mercado-Bettín, Daniel, Perroud, Marjorie, Stepanenko, Victor, Tan, Zeli, Grant, Luke, Ladwig, Robert, Mesman, Jorrit, Moore, Tadhg N., Shatwell, Tom, Vanderkelen, Inne, Austin, Jay A., DeGasperi, Curtis L., Dokulil, Martin, La Fuente, Sofia, Mackay, Eleanor B., Schladow, S. Geoffrey, Watanabe, Shohei, Marcé, Rafael, Pierson, Don C., Thiery, Wim, and Jennings, Eleanor

Published

2021

6. Smart renewable electricity portfolios in West Africa

Author

Sterl, Sebastian, Vanderkelen, Inne, Chawanda, Celray James, Russo, Daniel, Brecha, Robert J., van Griensven, Ann, van Lipzig, Nicole P. M., and Thiery, Wim

Published

2020

7. Possible role of anthropogenic climate change in the record-breaking 2020 Lake Victoria levels and floods.

Author

Pietroiusti, Rosa, Vanderkelen, Inne, Otto, Friederike E. L., Barnes, Clair, Temple, Lucy, Akurut, Mary, Bally, Philippe, van Lipzig, Nicole P. M., and Thiery, Wim

Subjects

*EFFECT of human beings on climate change, *FLOODS, *FLOOD risk, *SHORELINES, *RAINFALL, *MODES of variability (Climatology), *WATERSHEDS

Abstract

Heavy rainfall in eastern Africa between late 2019 and mid 2020 caused devastating floods and landslides throughout the region. These rains drove the levels of Lake Victoria to a record-breaking maximum in the second half of May 2020. The combination of high lake levels, consequent shoreline flooding, and flooding of tributary rivers caused hundreds of casualties and damage to housing, agriculture, and infrastructure in the riparian countries of Uganda, Kenya, and Tanzania. Media and government reports linked the heavy precipitation and floods to anthropogenic climate change, but a formal scientific attribution study has not been carried out so far. In this study, we characterize the spatial extent and impacts of the floods in the Lake Victoria basin and then investigate to what extent human-induced climate change influenced the probability and magnitude of the record-breaking lake levels and associated flooding by applying a multi-model extreme event attribution methodology. Using remote-sensing-based flood mapping tools, we find that more than 29 000 people living within a 50 km radius of the lake shorelines were affected by floods between April and July 2020. Precipitation in the basin was the highest recorded in at least 3 decades, causing lake levels to rise by 1.21 m between late 2019 and mid 2020. The flood, defined as a 6-month rise in lake levels as extreme as that observed in the lead-up to May 2020, is estimated to be a 63-year event in the current climate. Based on observations and climate model simulations, the best estimate is that the event has become more likely by a factor of 1.8 in the current climate compared to a pre-industrial climate and that in the absence of anthropogenic climate change an event with the same return period would have led lake levels to rise by 7 cm less than observed. Nonetheless, uncertainties in the attribution statement are relatively large due to large natural variability and include the possibility of no observed attributable change in the probability of the event (probability ratio, 95 % confidence interval 0.8–15.8) or in the magnitude of lake level rise during an event with the same return period (magnitude change, 95 % confidence interval 0–14 cm). In addition to anthropogenic climate change, other possible drivers of the floods and their impacts include human land and water management, the exposure and vulnerability of settlements and economic activities located in flood-prone areas, and modes of climate variability that modulate seasonal precipitation. The attribution statement could be strengthened by using a larger number of climate model simulations, as well as by quantitatively accounting for non-meteorological drivers of the flood and potential unforced modes of climate variability. By disentangling the role of anthropogenic climate change and natural variability in the high-impact 2020 floods in the Lake Victoria basin, this paper contributes to a better understanding of changing hydrometeorological extremes in eastern Africa and the African Great Lakes region. [ABSTRACT FROM AUTHOR]

Published

2024

8. Possible role of anthropogenic climate change in the record-breaking 2020 Lake Victoria levels and floods.

Author

Pietroiusti, Rosa, Vanderkelen, Inne, Otto, Friederike E. L., Barnes, Clair, Temple, Lucy, Akurut, Mary, Bally, Philippe, van Lipzig, Nicole P. M., and Thiery, Wim

Subjects

*EFFECT of human beings on climate change, *FLOODS, *FLOOD risk, *SHORELINES, *MODES of variability (Climatology), *RAINFALL, *WATERSHEDS

Abstract

Heavy rainfall in East Africa between late 2019 and mid 2020 caused devastating floods and landslides throughout the region. These rains drove the levels of Lake Victoria to a record-breaking maximum in the second half of May 2020. The combination of high lake levels, consequent shoreline flooding, and flooding of tributary rivers caused hundreds of casualties and damage to housing, agriculture and infrastructure in the riparian countries of Uganda, Kenya and Tanzania. Media and government reports linked the heavy precipitation and floods to anthropogenic climate change, but a formal scientific attribution study has not been carried out so far. In this study, we characterise the spatial extent and impacts of the floods in the Lake Victoria basin, and then investigate to what extent human-induced climate change influenced the probability and magnitude of the record-breaking lake levels and associated flooding, by applying a multi-model extreme event attribution methodology. Using remote sensing-based flood mapping tools, we find that more than 29 thousand people living within a 50 km radius of the lake shorelines were affected by floods between April and July 2020. Precipitation in the basin was the highest recorded in at least three decades, causing lake levels to rise by 1.21 m between late 2019 and mid 2020. The flood, defined as a 6-month rise in lake levels as extreme as that observed in the lead-up to May 2020, is estimated to be a 63-year event in the current climate. Based on observations and climate model simulations, the best estimate is that the event has become more likely by a factor of 1.8 in the current climate compared to a pre-industrial climate, and that in the absence of anthropogenic climate change an event with the same return period would have led lake levels to rise by 7 cm less than observed. Nonetheless, uncertainties in the attribution statement are relatively large due to large natural variability, and include the possibility of no observed attributable change in the probability of the event (probability ratio, 95% confidence interval 0.8 - 15.8) or in the magnitude of lake level rise during an event with the same return period (magnitude change, 95% confidence interval 0 - 14 cm). In addition to anthropogenic climate change, other possible drivers of the floods and their impacts include human land and water management, the exposure and vulnerability of settlements and economic activities located in flood-prone areas, and modes of climate variability that modulate seasonal precipitation. The attribution statement could be strengthened by using a larger number of climate model simulations, as well as by quantitatively accounting for non-meteorological drivers of the flood and potential unforced modes of climate variability. By disentangling the role of anthropogenic climate change and natural variability in the high-impact 2020 floods in the Lake Victoria basin, this paper contributes to a better understanding of changing hydrometeorological extremes in East Africa and the African Great Lakes region. [ABSTRACT FROM AUTHOR]

Published

2023

9. The biogeophysical effects of idealized land cover and land management changes in Earth system models.

Author

De Hertog, Steven J., Havermann, Felix, Vanderkelen, Inne, Guo, Suqi, Luo, Fei, Manola, Iris, Coumou, Dim, Davin, Edouard L., Duveiller, Gregory, Lejeune, Quentin, Pongratz, Julia, Schleussner, Carl-Friedrich, Seneviratne, Sonia I., and Thiery, Wim

Subjects

LAND management, LAND cover, EARTH (Planet), SURFACE temperature, CONSORTIA, COMMUNITIES

Abstract

Land cover and land management change (LCLMC) has been highlighted for its critical role in mitigation scenarios, both in terms of global mitigation and local adaptation. Yet, the climate effect of individual LCLMC options, their dependence on the background climate and the local vs. non-local responses are still poorly understood across different Earth system models (ESMs). Here we simulate the climatic effects of LCLMC using three state-of-the-art ESMs, including the Community Earth System Model (CESM), the Max Planck Institute for Meteorology Earth System Model (MPI-ESM) and the European Consortium Earth System Model (EC-EARTH). We assess the LCLMC effects using the following four idealized experiments: (i) a fully afforested world, (ii) a world fully covered by cropland, (ii) a fully afforested world with extensive wood harvesting and (iv) a full-cropland world with extensive irrigation. In these idealized sensitivity experiments, performed under present-day climate conditions, the effects of the different LCLMC strategies represent an upper bound for the potential of global mitigation and local adaptation. To disentangle the local and non-local effects from the LCLMC, a checkerboard-like LCLMC perturbation, i.e. alternating grid boxes with and without LCLMC, is applied. The local effects of deforestation on surface temperature are largely consistent across the ESMs and the observations, with a cooling in boreal latitudes and a warming in the tropics. However, the energy balance components driving the change in surface temperature show less consistency across the ESMs and the observations. Additionally, some biases exist in specific ESMs, such as a strong albedo response in CESM mid-latitudes and a soil-thawing-driven warming in boreal latitudes in EC-EARTH. The non-local effects on surface temperature are broadly consistent across ESMs for afforestation, though larger model uncertainty exists for cropland expansion. Irrigation clearly induces a cooling effect; however, the ESMs disagree whether these are mainly local or non-local effects. Wood harvesting is found to have no discernible biogeophysical effects on climate. Overall, our results underline the potential of ensemble simulations to inform decision making regarding future climate consequences of land-based mitigation and adaptation strategies. [ABSTRACT FROM AUTHOR]

Published

2023

10. Continental heat storage: contributions from the ground, inland waters, and permafrost thawing.

Author

Cuesta-Valero, Francisco José, Beltrami, Hugo, García-García, Almudena, Krinner, Gerhard, Langer, Moritz, MacDougall, Andrew H., Nitzbon, Jan, Peng, Jian, von Schuckmann, Karina, Seneviratne, Sonia I., Thiery, Wim, Vanderkelen, Inne, and Wu, Tonghua

Subjects

BODIES of water, PERMAFROST, HEAT storage, ENERGY storage, LATENT heat, THAWING, CARBON in soils

Abstract

Heat storage within the Earth system is a fundamental metric for understanding climate change. The current energy imbalance at the top of the atmosphere causes changes in energy storage within the ocean, the atmosphere, the cryosphere, and the continental landmasses. After the ocean, heat storage in land is the second largest term of the Earth heat inventory, affecting physical processes relevant to society and ecosystems, such as the stability of the soil carbon pool. Here, we present an update of the continental heat storage, combining for the first time the heat in the land subsurface, inland water bodies, and permafrost thawing. The continental landmasses stored 23.8 ± 2.0 × 10 21 J during the period 1960–2020, but the distribution of heat among the three components is not homogeneous. The sensible diffusion of heat through the ground accounts for ∼90 % of the continental heat storage, with inland water bodies and permafrost degradation (i.e. latent heat) accounting for ∼0.7 % and ∼9 % of the continental heat, respectively. Although the inland water bodies and permafrost soils store less heat than the solid ground, we argue that their associated climate phenomena justify their monitoring and inclusion in the Earth heat inventory. [ABSTRACT FROM AUTHOR]

Published

2023

11. The biogeophysical effects of idealized land cover and land management changes in Earth System Models.

Author

Hertog, Steven Johan De, Havermann, Felix, Vanderkelen, Inne, Guo, Suqi, Luo, Fei, Manola, Iris, Coumou, Dim, Davin, Edouard Léopold, Duveiller, Gregory, Lejeune, Quentin, Pongratz, Julia, Schleussner, Carl-Friedrich, Seneviratne, Sonia Isabelle, and Thiery, Wim

Subjects

LAND management, LAND cover, EARTH (Planet), SURFACE temperature, CONSORTIA, COMMUNITIES

Abstract

Land cover and land management change (LCLMC) has been highlighted for its critical role in mitigation scenarios, both in terms of global mitigation and local adaptation. Yet, the climate effect of individual LCLMC options, their dependence on the background climate and the local vs. non-local responses are still poorly understood across different Earth System Models (ESMs). Here we simulate the climatic effects of LCLMC using three state-of-the-art ESMs, including the Community Earth System Model (CESM), the Max Planck Institute for Meteorology Earth System Model (MPI-ESM) and the European Consortium Earth System Model (EC-EARTH). We assess the LCLMC effects using four idealized experiments: (i) a fully afforested world, (ii) a world fully covered by cropland, (ii) a fully afforested world with extensive wood harvesting, and (iv) a full cropland world with extensive irrigation. In these idealized sensitivity experiments, performed under present-day climate conditions, the effects of the different LCLMC strategies represent an upper bound for the potential of global mitigation and local adaptation. To disentangle the local and non-local effects from the LCLMC, a checkerboard-like LCLMC perturbation, i.e., alternating grid boxes with and without LCLMC, is applied. The local effects of deforestation on surface temperature are largely consistent across the ESMs and the observations, with a cooling in boreal latitudes and a warming in the tropics. However, the energy balance components driving the change in surface temperature show less consistency across the ESMs and the observations. Additionally, some biases exist in specific ESMs, such as a strong albedo response in CESM mid-latitudes and a soil thawing driven warming in boreal latitudes in EC-EARTH. The non-local effects on surface temperature are broadly consistent across ESMs for afforestation, though larger model uncertainty exists for cropland expansion. Irrigation clearly induces a cooling effect, however; the ESMs disagree whether these are mainly local or non-local effects. Wood harvesting is found to have no discernible biogeophysical effects on climate. Our results overall underline the potential of ensemble simulations to inform decision making regarding future climate consequences of land-based mitigation and adaptation strategies. [ABSTRACT FROM AUTHOR]

Published

2023

12. Implementation and Evaluation of Irrigation Techniques in the Community Land Model.

Author

Yao, Yi, Vanderkelen, Inne, Lombardozzi, Danica, Swenson, Sean, Lawrence, David, Jägermeyr, Jonas, Grant, Luke, and Thiery, Wim

Subjects

*ENERGY budget (Geophysics), *IRRIGATION, *COMMUNITIES, *IRRIGATION water, *WATER withdrawals, *WATER management

Abstract

Several previous studies have highlighted the irrigation‐induced impacts on the global and regional water cycle, energy budget, and near‐surface climate. While land models are widely used to address this question, the implementations of irrigation in these models vary in complexity. Here, we expand the representation of irrigation in Community Land Model to enable six different irrigation methods. We find that using a combination of irrigation methods, including default, sprinkler, flood and paddy techniques performs best as determined by evaluating the simulated irrigation water withdrawals against observations, and therefore select this combination as the new irrigation scheme. Then, the impact of the new irrigation scheme on surface fluxes is evaluated and detected using single‐point simulations. Finally, the global and regional irrigation‐induced impacts on surface energy and water fluxes are compared using both the original and the new irrigation scheme. The new irrigation scheme substantially reduces the bias and root‐mean‐square error of simulated irrigation water withdrawal in the USA and other countries, but considerably overestimates withdrawals in Central China. Results of single‐point experiments show that different irrigation methods have different effects on surface fluxes, while the magnitudes are small. At the global scale, the new scheme enlarges the irrigation‐induced impacts on water and energy variables relative to the original scheme, with varying magnitudes across regions. Overall, our results suggest that this newly developed scheme is a better tool for simulating irrigation‐induced impacts on climate, and highlight the added value of incorporating human water management in Earth system models. Plain Language Summary: Knowing the effects of irrigation on the water and energy cycle is important, as it helps us to understand better how irrigation may affect the near‐surface climate such as dampening heat extremes and increasing local air humidity. Land models are widely used for this purpose. However, in most of these models, different irrigation techniques are currently not considered. In this study, we develop a new irrigation scheme for the Community Land Model, and evaluate it by comparing modeled and observed irrigation water withdrawals and surface energy and water fluxes. Results show that this new scheme performs better in simulating irrigation water withdrawals in most countries. Results of one‐dimensional simulations show that different irrigation methods have small but varying impacts on surface fluxes. At the global and regional scale, incorporating more realistic irrigation methods enlarges the effects of irrigation on water and energy variables. We therefore conclude that improving the realism of irrigation in models can help us to improve our understanding of how irrigation affects climate through altered water and energy fluxes. Key Points: A newly‐developed irrigation module considering different irrigation methods is implemented in Community Land ModelThe new irrigation scheme shows a better performance of simulating irrigation water withdrawal against the original moduleDifferent irrigation methods have different effects on water cycle and energy budgets, changing regional irrigation‐induced impacts [ABSTRACT FROM AUTHOR]

Published

2022

13. A framework for ensemble modelling of climate change impacts on lakes worldwide: the ISIMIP Lake Sector.

Author

Golub, Malgorzata, Thiery, Wim, Marcé, Rafael, Pierson, Don, Vanderkelen, Inne, Mercado-Bettin, Daniel, Woolway, R. Iestyn, Grant, Luke, Jennings, Eleanor, Kraemer, Benjamin M., Schewe, Jacob, Zhao, Fang, Frieler, Katja, Mengel, Matthias, Bogomolov, Vasiliy Y., Bouffard, Damien, Côté, Marianne, Couture, Raoul-Marie, Debolskiy, Andrey V., and Droppers, Bram

Subjects

CLIMATE change models, LAKES, CLIMATE change, WATER quality, PLANT phenology, GRID cells, WATER temperature

Abstract

Empirical evidence demonstrates that lakes and reservoirs are warming across the globe. Consequently, there is an increased need to project future changes in lake thermal structure and resulting changes in lake biogeochemistry in order to plan for the likely impacts. Previous studies of the impacts of climate change on lakes have often relied on a single model forced with limited scenario-driven projections of future climate for a relatively small number of lakes. As a result, our understanding of the effects of climate change on lakes is fragmentary, based on scattered studies using different data sources and modelling protocols, and mainly focused on individual lakes or lake regions. This has precluded identification of the main impacts of climate change on lakes at global and regional scales and has likely contributed to the lack of lake water quality considerations in policy-relevant documents, such as the Assessment Reports of the Intergovernmental Panel on Climate Change (IPCC). Here, we describe a simulation protocol developed by the Lake Sector of the Inter-Sectoral Impact Model Intercomparison Project (ISIMIP) for simulating climate change impacts on lakes using an ensemble of lake models and climate change scenarios for ISIMIP phases 2 and 3. The protocol prescribes lake simulations driven by climate forcing from gridded observations and different Earth system models under various representative greenhouse gas concentration pathways (RCPs), all consistently bias-corrected on a 0.5 ∘ × 0.5 ∘ global grid. In ISIMIP phase 2, 11 lake models were forced with these data to project the thermal structure of 62 well-studied lakes where data were available for calibration under historical conditions, and using uncalibrated models for 17 500 lakes defined for all global grid cells containing lakes. In ISIMIP phase 3, this approach was expanded to consider more lakes, more models, and more processes. The ISIMIP Lake Sector is the largest international effort to project future water temperature, thermal structure, and ice phenology of lakes at local and global scales and paves the way for future simulations of the impacts of climate change on water quality and biogeochemistry in lakes. [ABSTRACT FROM AUTHOR]

Published

2022

14. Evaluating a reservoir parametrization in the vector-based global routing model mizuRoute (v2.0.1) for Earth system model coupling.

Author

Vanderkelen, Inne, Gharari, Shervan, Mizukami, Naoki, Clark, Martyn P., Lawrence, David M., Swenson, Sean, Pokhrel, Yadu, Hanasaki, Naota, van Griensven, Ann, and Thiery, Wim

Subjects

*HYDROLOGIC cycle, *RESERVOIRS, *HYDROLOGIC models, *IRRIGATION water, *WATER management, *STREAMFLOW, *LAKES

Abstract

Human-controlled reservoirs have a large influence on the global water cycle. While global hydrological models use generic parameterizations to model dam operations, the representation of reservoir regulation is still lacking in many Earth system models. Here we implement and evaluate a widely used reservoir parametrization in the global river-routing model mizuRoute, which operates on a vector-based river network resolving individual lakes and reservoirs and is currently being coupled to an Earth system model. We develop an approach to determine the downstream area over which to aggregate irrigation water demand per reservoir. The implementation of managed reservoirs is evaluated by comparing them to simulations ignoring inland waters and simulations with reservoirs represented as natural lakes using (i) local simulations for 26 individual reservoirs driven by observed inflows and (ii) global-domain simulations driven by runoff from the Community Land Model. The local simulations show the clear added value of the reservoir parametrization, especially for simulating storage for large reservoirs with a multi-year storage capacity. In the global-domain application, the implementation of reservoirs shows an improvement in outflow and storage compared to the no-reservoir simulation, but a similar performance is found compared to the natural lake parametrization. The limited impact of reservoirs on skill statistics could be attributed to biases in simulated river discharge, mainly originating from biases in simulated runoff from the Community Land Model. Finally, the comparison of modelled monthly streamflow indices against observations highlights that including dam operations improves the streamflow simulation compared to ignoring lakes and reservoirs. This study overall underlines the need to further develop and test runoff simulations and water management parameterizations in order to improve the representation of anthropogenic interference of the terrestrial water cycle in Earth system models. [ABSTRACT FROM AUTHOR]

Published

2022

15. Continental heat storage: Contributions from ground, inland waters, and permafrost thawing.

Author

Cuesta-Valero, Francisco José, Beltrami, Hugo, García-García, Almudena, Krinner, Gerhard, Langer, Moritz, MacDougall, Andrew H., Nitzbon, Jan, Jian Peng, Schuckmann, Karina von, Seneviratne, Sonia I., Smith, Noah, Thiery, Wim, Vanderkelen, Inne, and Tonghua Wu

Subjects

HEAT storage, PERMAFROST, THAWING, BODIES of water, TUNDRAS, ENERGY storage, CRYOSPHERE

Abstract

Heat storage within the Earth system is a fundamental metric to understand climate change. The current energy imbalance at the top of the atmosphere causes changes in energy storage within the ocean, the atmosphere, the cryosphere, and the continental landmasses. After the ocean, heat storage in land is the second largest term of the Earth heat inventory, affecting physical processes relevant to society and ecosystems, such as the stability of the soil carbon pool. Here, we present an update of the continental heat storage combining for the first time the heat in the land subsurface, inland water bodies, and permafrost thawing. The continental landmasses stored 23.9±0.4×1021 J during the period 1960-2020, but the distribution of heat among the three components is not homogeneous. The ground stores ~90 % of the continental heat storage, with inland water bodies and permafrost degradation accounting for ~0.7 % and ~9 % of the continental heat, respectively. Although the inland water bodies and permafrost soils store less heat than the ground, we argue that their associated climate phenomena justify their monitoring and inclusion in the Earth heat inventory. [ABSTRACT FROM AUTHOR]

Published

2022

16. The biogeophysical effects of idealized land cover and land management changes in Earth system models.

Author

De Hertog, Steven J., Havermann, Felix, Vanderkelen, Inne, Guo, Suqi, Luo, Fei, Manola, Iris, Coumou, Dim, Davin, Edouard L., Duveiller, Gregory, Lejeune, Quentin, Pongratz, Julia, Schleussner, Carl-Friedrich, Seneviratne, Sonia I., and Thiery, Wim

Subjects

LAND management, LAND cover, EARTH (Planet), SURFACE temperature, CONSORTIA, COMMUNITIES

Abstract

Land cover and land management change (LCLMC) has been highlighted for its critical role in mitigation scenarios in terms of both global mitigation and local adaptation. Yet, the climate effect of individual LCLMC options, their dependence on the background climate, and the local vs. non-local responses are still poorly understood across different Earth system models (ESMs). Here we simulate the climatic effects of LCLMC using three state-of-the-art ESMs, including the Community Earth System Model (CESM), the Max Planck Institute for Meteorology Earth System Model (MPI-ESM), and the European Consortium Earth System Model (EC-EARTH). We assess the LCLMC effects using four idealized experiments: (i) a fully afforested world, (ii) a world fully covered by cropland, (iii) a fully afforested world with extensive wood harvesting, and (iv) a full cropland world with extensive irrigation. In these idealized sensitivity experiments performed under present-day climate conditions, the effects of the different LCLMC strategies represent an upper bound for the potential of global mitigation and local adaptation. To disentangle the local and non-local effects from the LCLMC, a checkerboard-like LCLMC perturbation, i.e. alternating grid boxes with and without LCLMC, is applied. The local effects of deforestation on surface temperature are largely consistent across the ESMs and the observations, with a cooling in boreal latitudes and a warming in the tropics. However, the energy balance components driving the change in surface temperature show less consistency across the ESMs and the observations. Additionally, some biases exist in specific ESMs, such as a strong albedo response in CESM mid-latitudes and a soil-thawing-driven warming in boreal latitudes in EC-EARTH. The non-local effects on surface temperature are broadly consistent across ESMs for afforestation, though larger model uncertainty exists for cropland expansion. Irrigation clearly induces a cooling effect; however, the ESMs disagree regarding whether these are mainly local or non-local effects. Wood harvesting is found to have no discernible biogeophysical effects on climate. Our results overall underline the potential of ensemble simulations to inform decision-making regarding future climate consequences of land-based mitigation and adaptation strategies. [ABSTRACT FROM AUTHOR]

Published

2022

17. Evaluation of High-Resolution Precipitation Products over the Rwenzori Mountains (Uganda).

Author

Nakulopa, Faluku, Vanderkelen, Inne, Van de Walle, Jonas, van Lipzig, Nicole P. M., Tabari, Hossein, Jacobs, Liesbet, Tweheyo, Collins, Dewitte, Olivier, and Thiery, Wim

Subjects

*PROBABILITY density function, *LANDSLIDES, *PRECIPITATION probabilities, *ATMOSPHERIC models, *AGRICULTURAL productivity, *HYDROLOGIC models

Abstract

The Rwenzori Mountains, in southwest Uganda, are prone to precipitation-related hazards such as flash floods and landslides. These natural hazards highly impact the lives and livelihoods of the people living in the region. However, our understanding of the precipitation patterns and their impact on related hazardous events and/or agricultural productivity is hampered by a dearth of in situ precipitation observations. Here, we propose an evaluation of gridded precipitation products as potential candidates filling this hiatus. We evaluate three state-of-the-art gridded products, the ERA5 reanalysis, IMERG satellite observations, and a simulation from the convection-permitting climate model (CPM), COSMO-CLM, for their ability to represent precipitation totals, timing, and precipitation probability density function. The evaluation is performed against observations from 11 gauge stations that provide at least 2.5 years of hourly and half-hourly data, recorded between 2011 and 2016. Results indicate a poor performance of ERA5 with a persistent wet bias, mostly for stations in the rain shadow of the mountains. IMERG gives the best representation of the precipitation totals as indicated by bias score comparisons. The CPM outperforms both ERA5 and IMERG in representing the probability density function, while both IMERG and the CPM have a good skill in capturing precipitation seasonal and diurnal cycles. The better performance of CPM is attributable to its higher resolution. This study highlights the potential of using IMERG and CPM precipitation estimates for hydrological and impact modeling over the Rwenzori Mountains, preferring IMERG for precipitation totals and CPM for precipitation extremes. [ABSTRACT FROM AUTHOR]

Published

2022

18. A new approach for assessing climate change impacts in ecotron experiments.

Author

Vanderkelen, Inne, Zschleischler, Jakob, Gudmundsson, Lukas, Keuler, Klaus, Rineau, Francois, Beenaerts, Natalie, Vangronsveld, Jaco, and Thiery, Wim

Subjects

CLIMATE change, METEOROLOGICAL stations, ATMOSPHERIC models, EXPERIMENTAL design, DOWNSCALING (Climatology)

Abstract

Ecotron facilities allow accurate control of many environmental variables coupled with extensive monitoring of ecosystem processes. They therefore require multivariate perturbation of climate variables, close to what is observed in the field and projections for the future, preserving the co-variances between variables and the projected changes in variability. Here we present a new experimental design for studying climate change impacts on terrestrial ecosystems and apply it to the UHasselt Ecotron Experiment. The new methodology consists of generating climate forcing along a gradient representative of increasingly high global mean temperature anomalies and uses data derived from the best available regional climate model (RCM) projection. We first identified the best performing regional climate model (RCM) simulation for the ecotron site from the Coordinated Regional Downscaling Experiment in the European Domain (EURO-CORDEX) ensemble with a 0.11° (12.5 km) resolution based on two criteria: (i) highest skill of the simulations compared to observations from a nearby weather station and (ii) representativeness of the multi-model mean in future projections. Our results reveal that no single RCM simulation has the best score for all possible combinations of the four meteorological variables and evaluation metrics considered. Out of the six best performing simulations, we selected the simulation with the lowest bias for precipitation (CCLM4-8-17/EC-EARTH), as this variable is key to ecosystem functioning and model simulations deviated the most for this variable, with values ranging up to double the observed values. The time window is subsequently selected from the RCM projection for each ecotron unit based on the global mean temperature of the driving Global Climate Model (GCM). The ecotron units are forced with 3-hourly output from the RCM projections of the five-year period spanning the year in which the global mean temperature crosses the predefined values. With the new approach, Ecotron facilities become able to assess ecosystem responses on changing climatic conditions, while accounting for the co-variation between climatic variables and their projection in variability, well representing possible compound events. The gradient approach will allow to identify possible threshold and tipping points. [ABSTRACT FROM AUTHOR]

Published

2019

19. Modelling the water balance of Lake Victoria (East Africa) - Part 1: Observational analysis.

Author

Vanderkelen, Inne, van Lipzig, Nicole P. M., and Thiery, Wim

Subjects

WATER balance (Hydrology), METEOROLOGICAL precipitation, EVAPORATION (Meteorology), METEOROLOGICAL observations, DOWNSCALING (Climatology)

Abstract

Lake Victoria is the largest lake in Africa and one of the two major sources of the Nile river. The water level of Lake Victoria is determined by its water balance, consisting of precipitation on the lake, evaporation from the lake, inflow from tributary rivers and lake outflow, controlled by two hydropower dams. Due to a scarcity of in situ observations, previous estimates of individual water balance terms are characterized by substantial uncertainties, which means that the water balance is often not closed independently. In this first part of a two-paper series, we present a water balance model for Lake Victoria, using state-of-the-art remote sensing observations, high-resolution reanalysis downscaling and outflow values recorded at the dam. The uncalibrated computation of the individual water balance terms yields lake level fluctuations that closely match the levels retrieved from satellite altimetry. Precipitation is the main cause of seasonal and interannual lake level fluctuations, and on average causes the lake level to rise from May to July and to fall from August to December. Finally, our results indicate that the 2004-2005 drop in lake level can be about half attributed to a drought in the Lake Victoria Basin and about half to an enhanced outflow, highlighting the sensitivity of the lake level to human operations at the outflow dam. [ABSTRACT FROM AUTHOR]

Published

2018

20. Modelling the water balance of Lake Victoria (East Africa) - Part 2: Future projections.

Author

Vanderkelen, Inne, van Lipzig, Nicole P. M., and Thiery, Wim

Subjects

METEOROLOGICAL precipitation, CLIMATE change, WATER balance (Hydrology), EVAPORATION (Meteorology), DOWNSCALING (Climatology)

Abstract

Lake Victoria, the second largest freshwater lake in the world, is one of the major sources of the Nile river. The outlet to the Nile is controlled by two hydropower dams of which the allowed discharge is dictated by the Agreed Curve, an equation relating outflow to lake level. Some regional climate models project a decrease in precipitation and an increase in evaporation over Lake Victoria, with potential important implications for its water balance and resulting level. Yet, little is known about the potential consequences of climate change for the water balance of Lake Victoria. In this second part of a two-paper series, we feed a new water balance model for Lake Victoria presented in the first part with climate simulations available through the COordinated Regional Climate Downscaling Experiment (CORDEX) Africa framework. Our results reveal that most regional climate models are not capable of giving a realistic representation of the water balance of Lake Victoria and therefore require bias correction. For two emission scenarios (RCPs 4.5 and 8.5), the decrease in precipitation over the lake and an increase in evaporation are compensated by an increase in basin precipitation leading to more inflow. The future lake level projections show that the dam management scenario and not the emission scenario is the main controlling factor of the future water level evolution. Moreover, inter-model uncertainties are larger than emission scenario uncertainties. The comparison of four idealized future management scenarios pursuing certain policy objectives (electricity generation, navigation reliability and environmental conservation) uncovers that the only sustainable management scenario is mimicking natural lake level fluctuations by regulating outflow according to the Agreed Curve. The associated outflow encompasses, however, ranges from 14m³ day-1 (-85%) to 200m³ day-1 (C100%) within this ensemble, highlighting that future hydropower generation and downstream water availability may strongly change in the next decades even if dam management adheres to he Agreed Curve. Our results overall underline that managing the dam according to the Agreed Curve is a key prerequisite for sustainable future lake levels, but that under this management scenario, climate change might potentially induce profound changes in lake level and outflow volume. [ABSTRACT FROM AUTHOR]

Published

2018

21. Modelling the water balance of Lake Victoria (East Africa), part 2: future projections.

Author

van Lipzig, Nicole P. M., Vanderkelen, Inne, and Wim Thiery

Abstract

Lake Victoria, the second largest freshwater lake in the world, is one of the major sources of the Nile River. The outlet to the Nile is controlled by two hydropower dams of which the allowed discharge is dictated by the Agreed Curve, an equation relating outflow to lake level. Some regional climate models project a decrease of precipitation and an increase of evaporation over Lake Victoria, with potential important implications for its water balance and resulting level. Yet, nothing is known about the potential consequences of climate change for the water balance of Lake Victoria. In this second part of a two-paper series, we feed a new water balance model for Lake Victoria presented in the first part with climate simulations available through the Coordinated Regional Climate Downscaling Experiment (CORDEX) Africa framework. Our results reveal that most regional climate models are not capable of giving a realistic representation of the water balance of Lake Victoria. Therefore we applied two bias correction methods, resulting in both cases in a closed water balance. Our results reveal that for two emission scenarios (RCP4.5 and 8.5), the decrease in precipitation over the lake and an increase in evaporation are compensated by an increase in basin precipitation leading to more inflow. The future lake level projections show that the outflow scenario and not the emission scenario is the main controlling factor of the future water level evolution. Moreover, inter-model uncertainties are larger than emission scenario uncertainties. The comparison of four different outflow scenarios for the future uncovers that the only sustainable outflow scenario is regulating outflow following the Agreed Curve. The associated outflow encompasses however large uncertainties ranging up to 177 %, which are important to take into account regarding future hydropower generation and water availability downstream. [ABSTRACT FROM AUTHOR]

Published

2018