Nonlinear Processes in Geophysics (Oct 2023)

Comparative study of strongly and weakly coupled data assimilation with a global land–atmosphere coupled model

  • K. Kurosawa,
  • K. Kurosawa,
  • S. Kotsuki,
  • S. Kotsuki,
  • S. Kotsuki,
  • S. Kotsuki,
  • S. Kotsuki,
  • T. Miyoshi,
  • T. Miyoshi,
  • T. Miyoshi,
  • T. Miyoshi,
  • T. Miyoshi

DOI
https://doi.org/10.5194/npg-30-457-2023
Journal volume & issue
Vol. 30
pp. 457 – 479

Abstract

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This study explores coupled land–atmosphere data assimilation (DA) for improving weather and hydrological forecasts by assimilating soil moisture (SM) data. This study integrates a land DA component into a global atmospheric DA system of the Nonhydrostatic ICosahedral Atmospheric Model and the local ensemble transform Kalman filter (NICAM-LETKF) and performs both strongly and weakly coupled land–atmosphere DA experiments. We explore various types of coupled DA experiments by assimilating atmospheric observations and SM data simultaneously. The results show that analyzing atmospheric variables by assimilating SM data improves the SM analysis and forecasts and mitigates a warm bias in the lower troposphere where a dry SM bias exists. On the other hand, updating SM by assimilating atmospheric observations has detrimental impacts due to spurious error correlations between the atmospheric observations and land model variables. We also find that assimilating SM by strongly coupled DA is beneficial in the Sahel and equatorial Africa from May to October. These regions are characterized by seasonal variations in the precipitation patterns and benefit from updates in the atmospheric variables through SM DA during periods of increased precipitation. Additionally, these regions coincide with those identified in the previous studies, where a global initialization of SM would enhance the prediction skill of seasonal precipitation.