63 / 2023-07-25 07:39:24
Multi-Scale Factors Contributing to Increased Non-Tropical Cyclone Rainfall in the South China Sea in Autumn under Different ENSO Phases
ENSO,the South China Sea,non-tropical cyclone rainfall,ITCZ
Abstract Accepted
Feng Jie / Ocean University of China
Wang Fei / Jiangsu University of Science and Technology
Sheng Lifang / Ocean University of China
The rainfall in the South China Sea (SCS) usually peaks in autumn (September and October), with approximately 58% attributed to non-tropical cyclone (non-TC) rainfall. El Niño-Southern Oscillation (ENSO) is an important air-sea interaction phenomenon in tropical regions. Under specific phases, it can lead to an increase in non-TC rainfall in the SCS, and the mechanisms are required further exploration. This study investigated the multi-scale factors contributing to increased autumn non-TC rainfall in the SCS by using reanalysis, satellite, and station data. The results reveal that during La Niña years, the Intertropical Convergence Zone (ITCZ) can strengthen and accelerate northward in autumn, bringing heavy rainfall to the northern SCS. The stalled Madden-Julian Oscillation in the Indian Ocean-SCS region triggers a Gill response, strengthening the intensity of the ITCZ. Additionally, enhanced equatorial airflow, eastward-moving Continental High, and upper-level energy divergence all promote the northward movement of the ITCZ. However, during La Niña years, the anomalous strengthening, westward and southward extension of the Western Pacific Subtropical High (WPSH) can hinder the northward movement of the ITCZ. At this time, the northern SCS is predominantly controlled by the WPSH, with anomalous sea surface warming. Nevertheless, rainfall can still occur in the Northern SCS when there is wind shear in the lower levels. Surprisingly, strong El Niño years are also associated with increased rainfall. Positive surface latent heat flux anomaly and anomalous cyclone near the Beibu Gulf, combined with negative surface latent heat flux anomaly and anomalous anticyclone around the Bashi Strait, establish an anomalous zonal vertical circulation in the northern SCS. The anomalous circulation enhances the upward motion near the Hainan region, ultimately increasing the rainfall. This study further deepens the understanding of autumn rainfall in the SCS, aiming to provide a theoretical basis for rainfall prediction under climate change.
Important Date
  • Conference Date

    Nov 02

    2023

    to

    Nov 06

    2023

  • Nov 01 2023

    Contribution Submission Deadline

  • Nov 20 2023

    Draft paper submission deadline

  • Nov 05 2024

    Registration deadline

Sponsored By
Coastal Zones Under Intensifying Human Activities and Changing Climate: A
Regional Programme Integrating Science, Management and Society to Support
Ocean Sustainability (COASTAL-SOS)
Organized By
State Key Laboratory of Marine Environmental Science, Xiamen University
College of Ocean and Earth Sciences, Xiamen University
China-ASEAN College of Marine Sciences, Xiamen University Malaysia
Supported By
COASTAL-SOS
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