npj Climate and Atmospheric Science (Sep 2024)

Predictability and prediction skill of summertime East/Japan Sea surface temperature events

  • Youngji Joh,
  • SeonJu Lee,
  • Young-Gyu Park,
  • Thomas L. Delworth,
  • Gyundo Pak,
  • Liwei Jia,
  • William F. Cooke,
  • Colleen McHugh,
  • Young-Ho Kim,
  • Hyung-Gyu Lim

DOI
https://doi.org/10.1038/s41612-024-00754-7
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 14

Abstract

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Abstract The East/Japan Sea (EJS), a marginal sea of the Northwestern Pacific, is one of the ocean regions showing the most rapid warming and greatest increases in ocean heatwaves over the last several decades. Predictability and skillful prediction of the summer season EJS variability are crucial, given the increasing severity of ocean temperature events impacting fisheries and reinforcing climate conditions like the East Asian rainy season, which in turn affects adjacent high-population density areas over East Asia. We use observations and the Geophysical Fluid Dynamics Laboratory (GFDL) Seamless System for Prediction and Earth System Research (SPEAR) seasonal forecast system to investigate the summertime EJS Sea Surface Temperature (SST) predictability and prediction skill. The observations and seasonal prediction system show that the summer season EJS SST can be closely linked to the previous winter air-sea coupling and predictable 8–9 months in advance. The SPEAR seasonal prediction system demonstrates skillful forecast of EJS SST events from summer to late fall, with added skill for long-lead forecasts initialized in winter. We find that winter large-scale atmospheric circulations linked to Barents Sea variability can induce persistent surface wind anomalies and corresponding northward Ekman heat transport over the East China Sea. The ocean advection anomalies that enter the EJS in prior seasons appear to play a role in developing anomalous SST during summer, along with instantaneous atmospheric forcing, as the source of long-lead predictability. Our findings provide potential applications of large-scale ocean-atmosphere interactions in understanding and predicting seasonal variability of East Asian marginal seas.