State-resolved multimodal contributions to stratospheric polar vortex predictability
摘要
The dynamical basis of stratospheric polar vortex predictability remains unclear, particularly the relative roles of persistence, structural variability, and cross-level coupling. Here we provide a state-resolved and quantitative framework using eigen microstate theory applied to ERA5 geopotential height fields, enabling attribution of predictability to dynamically coherent circulation states via a mesoscopic Granger-causality approach. We show that short-term predictability is dominated by persistence of the leading stratospheric state, whereas extended predictability arises from higher-order stratospheric structures and tropospheric variability. These contributions exhibit strong lead-time dependence and become more distributed during sudden stratospheric warming events. Our results unify SPV predictability within a multimodal, state-resolved framework and provide a physically interpretable pathway for improving subseasonal-to-seasonal forecasts.
引用
@article{arxiv.2605.13417,
title = {State-resolved multimodal contributions to stratospheric polar vortex predictability},
author = {Shuo Yang and Dan Zhao and Tingting Xue and Chunhua Zeng and Yongwen Zhang and Xiaosong Chen},
journal= {arXiv preprint arXiv:2605.13417},
year = {2026}
}
备注
16 pages, 4 figures