可预测性
气候学
厄尔尼诺南方涛动
北方的
海面温度
环境科学
预测技巧
弹簧(装置)
海洋学
振荡(细胞信号)
航程(航空)
模式(计算机接口)
联轴节(管道)
气候变化
地质学
全球变化
气候系统
太平洋十年振荡
对流
全球变暖
气候模式
大气科学
气象学
海洋动力学
作者
Zepeng Mei,Shuheng Lin,Keyan Fang,Wanru Tang,Feifei Zhou,Fei Liu,Sen Zhao,Hao Wu,Jinbao Li,Zheng Zhao,Tinghai Ou,Xiaoxun Xie,Deliang Chen
标识
DOI:10.1073/pnas.2512725123
摘要
The El Niño-Southern Oscillation (ENSO) exhibits its weakest predictability during boreal spring, a phenomenon known as the Spring Predictability Barrier (SPB). The SPB arises from weak air-sea coupling that limits the growth and persistence of the ENSO signal. Improving springtime prediction therefore requires identifying oceanic regions most relevant for convection variability. Here, we introduce a Sea Surface Temperature Range Index (SRI), which quantifies the spatial extent of Sea surface temperatures favorable for convection. Using SRI, we show that regions exceeding 26 °C in the east-central Pacific and 28.5 °C in the eastern Atlantic during spring are critical for initiating persistent intense convection. The expansion of these convection-sensitive areas strengthens the Bjerknes feedback by modulating the Walker circulation, providing an effective predictor of ENSO evolution. We further develop a Long Short-Term Memory deep learning model incorporating SRI, which achieves higher predictive skill than the average of dynamical and statistical models, especially for multiyear La Niña events. These results underscore the central role of convection-sensitive oceanic regions in alleviating the SPB.
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