Data-Driven Solar Surface Flux Transport Modeling with Uncertainty Quantification

Katherine Keegan; Nina Bonaventura; Plinio Guzmán; Nishu Karna; Shea Hess-Webber; Spiridon Kasapis; Bibhuti Kumar Jha; Andrés Muñoz-Jaramillo

Data-Driven Solar Surface Flux Transport Modeling with Uncertainty Quantification

Katherine Keegan, Nina Bonaventura, Plinio Guzmán, Nishu Karna, Shea Hess-Webber, Spiridon Kasapis, Bibhuti Kumar Jha, Andrés Muñoz-Jaramillo

Published: 24 Sept 2025, Last Modified: 26 Dec 2025NeurIPS2025-AI4Science PosterEveryoneRevisionsBibTeXCC BY 4.0

Additional Submission Instructions: For the camera-ready version, please include the author names and affiliations, funding disclosures, and acknowledgements.

Track: Track 1: Original Research/Position/Education/Attention Track

Keywords: Forecasting, Uncertainty Quantification, Heliophysics

TL;DR: We present an ongoing effort to provide AI-driven and UQ-equipped forecasting pipeline for solar surface magnetic field evolution.

Abstract: Solar active regions (ARs) are areas of increased magnetic flux on the Sun's surface. Their downstream effects, including phenomena such as solar flares, Solar Energetic Particle events (SEPs) and coronal mass ejections (CMEs), can impair Earth- and space-based human infrastructure. To mitigate these dangers, the prediction of such events and their precursors --namely the ARs-- are necessary, and uncertainty quantification (UQ) of these predictions are crucial for subsequent human decision-making. In this manuscript, we present Active Region Characterization and Analysis of Dynamics and Evolution (ARCADE), an ongoing effort to provide AI-driven and UQ-equipped forecasting pipeline for solar surface magnetic field evolution. ARCADE is trained by propagating a ResNet through a numerical simulation of the solar surface magnetic field. In this work, we validate our numerical integrator against the state-of-the-art Advective Flux Transport model (AFT) and demonstrate that ARCADE offers high-accuracy forecasts with consistent uncertainty estimations. Moreover, ARCADE is the first model of surface magnetic evolution to produce forecast of the emergence of flux several hours into the future. Finally, we provide a convenient user interface for forecasting with UQ, accessible here: http://34.10.144.174:4000/. This work is a promising first step for hybrid physics-ML methods for solar magnetic field forecasting with UQ, offering clear interpretability and usability for heliophysicists and stakeholders in space weather prediction.

Submission Number: 304

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