Gauge-Equivariant Graph Neural Networks for Lattice Gauge Theories
Ali Rayat, Yaohang Li, Gia-Wei Chern
TLDR
Introduces a gauge-equivariant GNN that embeds non-Abelian symmetry into message passing for learning in lattice gauge theories.
Key contributions
- Develops a gauge-equivariant GNN for learning under site-dependent, local gauge symmetries.
- Embeds non-Abelian symmetry directly into message passing using matrix-valued, gauge-covariant features.
- Enables gauge-covariant transport across the lattice, capturing nonlocal correlations and loop structures.
- Validated across pure gauge, gauge-matter, and dynamical regimes, establishing a new learning paradigm.
Why it matters
This paper addresses a critical gap in ML for physics by providing a principled framework for local gauge symmetries. It enables more accurate and generalizable simulations of fundamental interactions and quantum matter. This approach could significantly advance our understanding of complex physical systems.
Original Abstract
Local gauge symmetry underlies fundamental interactions and strongly correlated quantum matter, yet existing machine-learning approaches lack a general, principled framework for learning under site-dependent symmetries, particularly for intrinsically nonlocal observables. Here we introduce a gauge-equivariant graph neural network that embeds non-Abelian symmetry directly into message passing via matrix-valued, gauge-covariant features and symmetry-compatible updates, extending equivariant learning from global to fully local symmetries. In this formulation, message passing implements gauge-covariant transport across the lattice, allowing nonlocal correlations and loop-like structures to emerge naturally from local operations. We validate the approach across pure gauge, gauge-matter, and dynamical regimes, establishing gauge-equivariant message passing as a general paradigm for learning in systems governed by local symmetry.
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