Abstract
We study the machine learning techniques applied to the lattice gauge theory's critical behavior, particularly to the confinement/deconfinement phase transition in the SU(2) and SU(3) gauge theories. We find that the neural network, trained on lattice configurations of gauge fields at an unphysical value of the lattice parameters as an input, builds up a gauge-invariant function, and finds correlations with the target observable that is valid in the physical region of the parameter space. In particular, if the algorithm aimed to predict the Polyakov loop as the deconfining order parameter, it builds a trace of the gauge group matrices along a closed loop in the time direction. As a result, the neural network, trained at one unphysical value of the lattice coupling $\beta$ predicts the order parameter in the whole region of the $\beta$ values with good precision. We thus demonstrate that the machine learning techniques may be used as a numerical analog of the analytical continuation from easily accessible but physically uninteresting regions of the coupling space to the interesting but potentially not accessible regions.
Highlights
The theory of strong interactions, quantum chromodynamics (QCD), exhibits several nonperturbative properties that lack so far a solid theoretical explanation
We find that the neural network, trained on lattice configurations of gauge fields at an unphysical value of the lattice parameters as an input, builds up a gauge-invariant function, and finds correlations with the target observable that is valid in the physical region of the parameter space
The neural network is able to find the correlations in the lattice data at one point of the lattice coupling, reconstruct the appropriate order parameter, and find the critical behavior of the system by applying the reconstructed operator to the full range of the lattice couplings including the interesting region of the real physical phase transition
Summary
The theory of strong interactions, quantum chromodynamics (QCD), exhibits several nonperturbative properties that lack so far a solid theoretical explanation This theory challenges scientists with the phenomena of confinement of color, mass-gap generation, and chiral symmetry breaking observed at low temperatures. The nonperturbative physics of QCD appears as a result of the gluon dynamics encoded in the non-Abelian gauge sector of the theory These issues can be addressed either in low-energy effective models or in firstprinciple numerical simulations in a lattice formulation of.
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