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Gauge Equivariant Neural Networks for Quantum Lattice Gauge Theories

Di Luo, Giuseppe Carleo, Bryan K. Clark, James Stokes

2021Physical Review Letters32 citationsDOIOpen Access PDF

Abstract

Gauge symmetries play a key role in physics appearing in areas such as quantum field theories of the fundamental particles and emergent degrees of freedom in quantum materials. Motivated by the desire to efficiently simulate many-body quantum systems with exact local gauge invariance, gauge equivariant neural-network quantum states are introduced, which exactly satisfy the local Hilbert space constraints necessary for the description of quantum lattice gauge theory with Z_{d} gauge group and non-Abelian Kitaev D(G) models on different geometries. Focusing on the special case of Z_{2} gauge group on a periodically identified square lattice, the equivariant architecture is analytically shown to contain the loop-gas solution as a special case. Gauge equivariant neural-network quantum states are used in combination with variational quantum Monte Carlo to obtain compact descriptions of the ground state wave function for the Z_{2} theory away from the exactly solvable limit, and to demonstrate the confining or deconfining phase transition of the Wilson loop order parameter.

Topics & Concepts

Lattice gauge theoryPhysicsHamiltonian lattice gauge theoryQuantum gauge theoryEquivariant mapGauge anomalyIntroduction to gauge theoryGauge theoryQuantum mechanicsGauge fixingSupersymmetric gauge theoryTheoretical physicsBRST quantizationLattice field theoryQuantumQuantum algorithmQuantum stateQuantum phasesQuantum field theoryGauge symmetryQuantum Monte CarloOpen quantum systemQuantum electrodynamicsMathematical physicsGauge bosonLattice model (finance)Quantum operationQuantum phase transitionQuantum processQuantum many-body systemsMachine Learning in Materials ScienceTopological Materials and Phenomena
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