JW-Flare: Accurate Solar Flare Forecasting Method Based on Multimodal Large Language Models
Abstract
Solar flares, the most powerful explosive phenomena in the solar system, may pose significant hazards to spaceborne satellites and ground-based infrastructure. Despite decades of intensive research, reliable flare prediction remains a challenging task. Large Language Models, as a milestone in artificial intelligence, exhibit exceptional general knowledge and next-token prediction capabilities. Here we introduce JW-Flare, the first Multimodal Large Language Models (MLLMs) explicitly trained for solar flare forecasting through fine-tuning on textual physic parameters of solar active regions and magnetic field images. This method demonstrates state-of-the-art (SOTA) performance for large flares prediction on the test dataset. It effectively identifies all 79 X-class flares from 18,949 test samples, yielding a True Skill Statistic (TSS) of 0.95 and a True Positive Rate (TPR) of 1.00, outperforming traditional predictive models. We further investigate the capability origins of JW-Flare through explainability experiments, revealing that solar physics knowledge acquired during pre-training contributes to flare forecasting performance. Additionally, we evaluate models of different parameter scales, confirming the Scaling_Law of Large Language Models in domain-specific applications, such as solar physics. This study marks a substantial advance in both the scale and accuracy of solar flare forecasting and opens a promising avenue for AI-driven methodologies in broader scientific domains.
Cite
@article{arxiv.2511.08970,
title = {JW-Flare: Accurate Solar Flare Forecasting Method Based on Multimodal Large Language Models},
author = {Mingfu Shao and Hui Wang and Yuyang Li and Jiaben Lin and Jifeng Liu and Baolin Tan and Juan Guo and Yin Zhang and Jing Huang and Jiangtao Su and Yingzi Sun and Haiqing Xu and Jie Chen and Suo Liu and Yuanyong Deng and Liyue Tong and Yang Bai and Cunshi Wang and Kaifan Ji and Yuqing Zhou},
journal= {arXiv preprint arXiv:2511.08970},
year = {2025}
}
Comments
12 pages, 5 figures