Autonomous Discovery of Particle Physics Theories from Experimental Data
Abstract
The search for physics beyond the Standard Model is hindered by a combinatorial explosion of possible theories. We introduce Albert, a neuro-symbolic artificial intelligence framework to systematically navigate this vast theory space. By encoding particle physics as a formal language, Albert generates tokenized sequences representing symmetries, particles, and interactions under a rule-based grammar, eliminating the hallucinations common in large language models. The reinforcement learning environment enforces first-principle theoretical constraints, computes observables with radiative corrections, and evaluates statistical likelihood via 2 analysis against experimental data. As a proof of concept, we train a 25-million-parameter transformer model using only legacy data from the Large Electron-Positron Collider, which contains no direct evidence of the top quark. Remarkably, Albert successfully rediscovered the Standard Model and autonomously inferred necessity and properties of the top quark, predicting its mass at 178.9 5.0~GeV, consistent with its modern measurement at the Large Hadron Collider. These results demonstrate the potential of AI-driven theory exploration as a rigorous, hallucination-free, and scalable paradigm for autonomous discovery of new physics.
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