The global water resources and use model WaterGAP v2.2e: description and evaluation of modifications and new features

Hannes Müller Schmied; Tim Trautmann; Sebastian Ackermann; Denise Cáceres; Martina Flörke; Helena Gerdener; Ellen Kynast; Thedini Asali Peiris; Leonie Schiebener; Maike Schumacher; Petra Döll

doi:10.5194/gmd-2023-213

The global water resources and use model WaterGAP v2.2e: description and evaluation of modifications and new features

Hannes Müller Schmied^*, Tim Trautmann, Sebastian Ackermann, Denise Cáceres, Martina Flörke, Helena Gerdener, Ellen Kynast, Thedini Asali Peiris, Leonie Schiebener, Maike Schumacher, Petra Döll

^*Kontaktforfatter

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

26 Citationer (Scopus)

121 Downloads (Pure)

Abstract

Water – Global Assessment and Prognosis (WaterGAP) is a modeling approach for quantifying water resources and water use for all land areas of the Earth that has served science and society since 1996. In this paper, the refinements, new algorithms, and new data of the most recent model version v2.2e are described, together with a thorough evaluation of the simulated water use, streamflow, and terrestrial water storage anomaly against observation data. WaterGAP v2.2e improves the handling of inland sinks and now excludes not only large but also small human-made reservoirs when simulating naturalized conditions. The reservoir and non-irrigation water use data were updated. In addition, the model was calibrated against an updated and extended data set of streamflow observations at 1509 gauging stations. The modifications resulted in a small decrease in the estimated global renewable water resources. The model can now be started using prescribed water storages and other conditions, facilitating data assimilation and near-real-time monitoring and forecast simulations. For specific applications, the model can consider the output of a glacier model, approximate the effect of rising CO₂ concentrations on evapotranspiration, or calculate the water temperature in rivers. In the paper, the publicly available standard model output is described, and caveats of the model version are provided alongside the description of the model setup in the ISIMIP3 framework.

Originalsprog	Engelsk
Tidsskrift	Geoscientific Model Development
Vol/bind	17
Udgave nummer	23
Sider (fra-til)	8817-8852
Antal sider	36
ISSN	1991-959X
DOI	https://doi.org/10.5194/gmd-2023-213
Status	Udgivet - 12 dec. 2024

Bibliografisk note

Publisher Copyright:
© Author(s) 2024. This work is distributed under the Creative Commons Attribution 4.0 License.

FN’s Verdensmål

Denne publikation bidrager til følgende verdensmål

Adgang til dokumentet

10.5194/gmd-2023-213Licens: CC BY 4.0

MuellerSchmied-etal_2023_GMDdiscussions_preprintIndsendt manuskript, 1,57 MB
Open Access articleForlagets udgivne version, 1,57 MBLicens: CC BY 4.0

AUB Link

Søg efter materialet i Aalborg Universitetsbiblioteks søgemaskine

Andre filer og links

Link to publication in Scopus

1 Afsluttet
2 Igangværende

A Novel Synergy of Physics-based and Data-driven Methods for Reliable Hydrological Predictions under Changing Climate
Schumacher, M. (PI (principal investigator)), Forootan, E. (CoI (co-investigator)), Döll, P. (CoI (co-investigator)), Wedi, N. (CoI (co-investigator)), Bates, P. (CoI (co-investigator)), Jagdhuber, T. (CoI (co-investigator)) & van Dijk, A. I. (CoI (co-investigator))
Villum Fonden
01/04/2024 → 31/03/2029
Projekter: Projekt › Forskning
DANSk-LSM: Developing efficient multi-sensor Data Assimilation frameworks for integrating Earth ObservatioN Satellite data into Land Surface Models (DANSk-LSM)
Forootan, E. (PI (principal investigator)), Schumacher, M. (CoI (co-investigator)), Yang, F. (Projektdeltager) & Retegui Schiettekatte, L. A. (Projektdeltager)
Uddannelses- og Forskningsministeriet
01/09/2022 → 31/08/2026
Projekter: Projekt › Forskning
Translation of climate information into multilevel decision support for social adaptation, policy development, and resilience to water scarcity in the Horn of Africa Drylands
Schumacher, M. (PI (principal investigator)) & Forootan, E. (PI (principal investigator))
01/08/2020 → 01/09/2024
Projekter: Projekt › Forskning

AAU-Geodesy 2025 - Summer School - Satellite-Based Hydrological Data Assimilation
Forootan, E. (Deltager), Schumacher, M. (Deltager), Retegui Schiettekatte, L. A. (Deltager), Mehrnegar, N. (Deltager), Çakan, Ç. (Deltager) & Yang, F. (Deltager)
Impact

Citationsformater

Müller Schmied, H., Trautmann, T., Ackermann, S., Cáceres, D., Flörke, M., Gerdener, H., Kynast, E., Asali Peiris, T., Schiebener, L., Schumacher, M., & Döll, P. (2024). The global water resources and use model WaterGAP v2.2e: description and evaluation of modifications and new features. Geoscientific Model Development, 17(23), 8817-8852. https://doi.org/10.5194/gmd-2023-213

@article{4d77823093894f0a91b4800ead3a1dab,

title = "The global water resources and use model WaterGAP v2.2e: description and evaluation of modifications and new features",

abstract = "Water – Global Assessment and Prognosis (WaterGAP) is a modeling approach for quantifying water resources and water use for all land areas of the Earth that has served science and society since 1996. In this paper, the refinements, new algorithms, and new data of the most recent model version v2.2e are described, together with a thorough evaluation of the simulated water use, streamflow, and terrestrial water storage anomaly against observation data. WaterGAP v2.2e improves the handling of inland sinks and now excludes not only large but also small human-made reservoirs when simulating naturalized conditions. The reservoir and non-irrigation water use data were updated. In addition, the model was calibrated against an updated and extended data set of streamflow observations at 1509 gauging stations. The modifications resulted in a small decrease in the estimated global renewable water resources. The model can now be started using prescribed water storages and other conditions, facilitating data assimilation and near-real-time monitoring and forecast simulations. For specific applications, the model can consider the output of a glacier model, approximate the effect of rising CO2 concentrations on evapotranspiration, or calculate the water temperature in rivers. In the paper, the publicly available standard model output is described, and caveats of the model version are provided alongside the description of the model setup in the ISIMIP3 framework.",

author = "\{M{\"u}ller Schmied\}, Hannes and Tim Trautmann and Sebastian Ackermann and Denise C{\'a}ceres and Martina Fl{\"o}rke and Helena Gerdener and Ellen Kynast and \{Asali Peiris\}, Thedini and Leonie Schiebener and Maike Schumacher and Petra D{\"o}ll",

note = "Publisher Copyright: {\textcopyright} Author(s) 2024. This work is distributed under the Creative Commons Attribution 4.0 License.",

year = "2024",

month = dec,

day = "12",

doi = "10.5194/gmd-2023-213",

language = "English",

volume = "17",

pages = "8817--8852",

journal = "Geoscientific Model Development",

issn = "1991-959X",

publisher = "Copernicus Publications",

number = "23",

}

Müller Schmied, H, Trautmann, T, Ackermann, S, Cáceres, D, Flörke, M, Gerdener, H, Kynast, E, Asali Peiris, T, Schiebener, L, Schumacher, M & Döll, P 2024, 'The global water resources and use model WaterGAP v2.2e: description and evaluation of modifications and new features', Geoscientific Model Development, bind 17, nr. 23, s. 8817-8852. https://doi.org/10.5194/gmd-2023-213

TY - JOUR

T1 - The global water resources and use model WaterGAP v2.2e

T2 - description and evaluation of modifications and new features

AU - Müller Schmied, Hannes

AU - Trautmann, Tim

AU - Ackermann, Sebastian

AU - Cáceres, Denise

AU - Flörke, Martina

AU - Gerdener, Helena

AU - Kynast, Ellen

AU - Asali Peiris, Thedini

AU - Schiebener, Leonie

AU - Schumacher, Maike

AU - Döll, Petra

PY - 2024/12/12

Y1 - 2024/12/12

N2 - Water – Global Assessment and Prognosis (WaterGAP) is a modeling approach for quantifying water resources and water use for all land areas of the Earth that has served science and society since 1996. In this paper, the refinements, new algorithms, and new data of the most recent model version v2.2e are described, together with a thorough evaluation of the simulated water use, streamflow, and terrestrial water storage anomaly against observation data. WaterGAP v2.2e improves the handling of inland sinks and now excludes not only large but also small human-made reservoirs when simulating naturalized conditions. The reservoir and non-irrigation water use data were updated. In addition, the model was calibrated against an updated and extended data set of streamflow observations at 1509 gauging stations. The modifications resulted in a small decrease in the estimated global renewable water resources. The model can now be started using prescribed water storages and other conditions, facilitating data assimilation and near-real-time monitoring and forecast simulations. For specific applications, the model can consider the output of a glacier model, approximate the effect of rising CO2 concentrations on evapotranspiration, or calculate the water temperature in rivers. In the paper, the publicly available standard model output is described, and caveats of the model version are provided alongside the description of the model setup in the ISIMIP3 framework.

AB - Water – Global Assessment and Prognosis (WaterGAP) is a modeling approach for quantifying water resources and water use for all land areas of the Earth that has served science and society since 1996. In this paper, the refinements, new algorithms, and new data of the most recent model version v2.2e are described, together with a thorough evaluation of the simulated water use, streamflow, and terrestrial water storage anomaly against observation data. WaterGAP v2.2e improves the handling of inland sinks and now excludes not only large but also small human-made reservoirs when simulating naturalized conditions. The reservoir and non-irrigation water use data were updated. In addition, the model was calibrated against an updated and extended data set of streamflow observations at 1509 gauging stations. The modifications resulted in a small decrease in the estimated global renewable water resources. The model can now be started using prescribed water storages and other conditions, facilitating data assimilation and near-real-time monitoring and forecast simulations. For specific applications, the model can consider the output of a glacier model, approximate the effect of rising CO2 concentrations on evapotranspiration, or calculate the water temperature in rivers. In the paper, the publicly available standard model output is described, and caveats of the model version are provided alongside the description of the model setup in the ISIMIP3 framework.

UR - https://www.scopus.com/pages/publications/85212099813

U2 - 10.5194/gmd-2023-213

DO - 10.5194/gmd-2023-213

M3 - Journal article

AN - SCOPUS:85212099813

SN - 1991-959X

VL - 17

SP - 8817

EP - 8852

JO - Geoscientific Model Development

JF - Geoscientific Model Development

IS - 23

ER -

The global water resources and use model WaterGAP v2.2e: description and evaluation of modifications and new features

Abstract

Bibliografisk note

FN’s Verdensmål

Adgang til dokumentet

AUB Link

Andre filer og links

Fingeraftryk

Projekter

A Novel Synergy of Physics-based and Data-driven Methods for Reliable Hydrological Predictions under Changing Climate

DANSk-LSM: Developing efficient multi-sensor Data Assimilation frameworks for integrating Earth ObservatioN Satellite data into Land Surface Models (DANSk-LSM)

Translation of climate information into multilevel decision support for social adaptation, policy development, and resilience to water scarcity in the Horn of Africa Drylands

Impacts

AAU-Geodesy 2025 - Summer School - Satellite-Based Hydrological Data Assimilation

Citationsformater