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Physics-Driven Learning for Inverse Problems in Quantum Chromodynamics

High Energy Physics - Lattice 2025-01-13 v1 Machine Learning High Energy Physics - Phenomenology Nuclear Theory

Abstract

The integration of deep learning techniques and physics-driven designs is reforming the way we address inverse problems, in which accurate physical properties are extracted from complex data sets. This is particularly relevant for quantum chromodynamics (QCD), the theory of strong interactions, with its inherent limitations in observational data and demanding computational approaches. This perspective highlights advances and potential of physics-driven learning methods, focusing on predictions of physical quantities towards QCD physics, and drawing connections to machine learning(ML). It is shown that the fusion of ML and physics can lead to more efficient and reliable problem-solving strategies. Key ideas of ML, methodology of embedding physics priors, and generative models as inverse modelling of physical probability distributions are introduced. Specific applications cover first-principle lattice calculations, and QCD physics of hadrons, neutron stars, and heavy-ion collisions. These examples provide a structured and concise overview of how incorporating prior knowledge such as symmetry, continuity and equations into deep learning designs can address diverse inverse problems across different physical sciences.

Keywords

Cite

@article{arxiv.2501.05580,
  title  = {Physics-Driven Learning for Inverse Problems in Quantum Chromodynamics},
  author = {Gert Aarts and Kenji Fukushima and Tetsuo Hatsuda and Andreas Ipp and Shuzhe Shi and Lingxiao Wang and Kai Zhou},
  journal= {arXiv preprint arXiv:2501.05580},
  year   = {2025}
}

Comments

14 pages, 5 figures, submitted version to Nat Rev Phys

R2 v1 2026-06-28T21:01:59.147Z