Diagnosing modeling errors in global terrestrial water storage interannual variability

Publikation: Beitrag in FachzeitschriftForschungsartikelBeigetragenBegutachtung

Beitragende

  • Hoontaek Lee - , Juniorprofessur für Umweltfernerkundung, Max Planck Institute for Biogeochemistry (Autor:in)
  • Martin Jung - , Max Planck Institute for Biogeochemistry (Autor:in)
  • Nuno Carvalhais - , Max Planck Institute for Biogeochemistry, NOVA University Lisbon, Michael Stifel Center Jena for Data-driven and Simulation Science (Autor:in)
  • Tina Trautmann - , Max Planck Institute for Biogeochemistry (Autor:in)
  • Basil Kraft - , Max Planck Institute for Biogeochemistry (Autor:in)
  • Markus Reichstein - , Max Planck Institute for Biogeochemistry, Michael Stifel Center Jena for Data-driven and Simulation Science (Autor:in)
  • Matthias Forkel - , Juniorprofessur für Umweltfernerkundung (Autor:in)
  • Sujan Koirala - , Max Planck Institute for Biogeochemistry (Autor:in)

Abstract

Terrestrial water storage (TWS) is an integrative hydrological state that is key for our understanding of the global water cycle. The TWS observation from the GRACE missions has, therefore, been instrumental in the calibration and validation of hydrological models and understanding the variations in the hydrological storage. The models, however, still show significant uncertainties in reproducing observed TWS variations, especially for the interannual variability (IAV) at the global scale. Here, we diagnose the regions dominating the variance in globally integrated TWS IAV and the sources of the errors in two data-driven hydrological models that were calibrated against global TWS, snow water equivalent, evapotranspiration, and runoff data. We used (1) a parsimonious process-based hydrological model, the Strategies to INtegrate Data and BiogeochemicAl moDels (SINDBAD) framework and (2) a machine learning, physically based hybrid hydrological model (H2M) that combines a dynamic neural network with a water balance concept. While both models agree with the Gravity Recovery and Climate Experiment (GRACE) that global TWS IAV is largely driven by the semi-arid regions of southern Africa, the Indian subcontinent and northern Australia, and the humid regions of northern South America and the Mekong River basin, the models still show errors such as the overestimation of the observed magnitude of TWS IAV at the global scale. Our analysis identifies modeling error hotspots of the global TWS IAV, mostly in the tropical regions including the Amazon, sub-Saharan regions, and Southeast Asia, indicating that the regions that dominate global TWS IAV are not necessarily the same as those that dominate the error in global TWS IAV. Excluding those error hotspot regions in the global integration yields large improvements in the simulated global TWS IAV, which implies that model improvements can focus on improving processes in these hotspot regions. Further analysis indicates that error hotspot regions are associated with lateral flow dynamics, including both sub-pixel moisture convergence and across-pixel lateral river flow, or with interactions between surface processes and groundwater. The association of model deficiencies with land processes that delay the TWS variation could, in part, explain why the models cannot represent the observed lagged response of TWS IAV to precipitation IAV in hotspot regions that manifest as errors in global TWS IAV. Our approach presents a general avenue to better diagnose model simulation errors for global data streams to guide efficient and focused model development for regions and processes that matter the most.

Details

OriginalspracheEnglisch
Seiten (von - bis)1531-1563
Seitenumfang33
FachzeitschriftHydrology and earth system sciences
Jahrgang27 (2023)
Ausgabenummer7
PublikationsstatusVeröffentlicht - 14 Apr. 2023
Peer-Review-StatusJa

Externe IDs

ORCID /0000-0003-0363-9697/work/142252109

Schlagworte