Uncovering gauge-dependent critical order-parameter correlations by a stochastic gauge fixing at O(N)* and Ising* continuous transitions
Abstract
We study the O(N)* transitions that occur in the 3D Z2-gauge N-vector model, and the analogous Ising* transitions occurring in the 3D Z2-gauge Higgs model, corresponding to an N-vector model with N=1. At these transitions, gauge-invariant correlations behave as in the usual N-vector/Ising model. Instead, the nongauge invariant spin correlations are trivial and therefore the spin order parameter that characterizes the spontaneous breaking of the O(N) symmetry in standard N-vector/Ising systems is apparently absent. We define a novel gauge fixing procedure -- we name it stochastic gauge fixing -- that allows us to define a gauge-dependent vector field that orders at the transition and is therefore the appropriate order parameter for the O(N) symmetry breaking. To substantiate this approach, we perform numerical simulations for N=3 and N=1. A finite-size scaling analysis of the numerical data allows us to confirm the general scenario: the gauge-fixed spin correlation functions behave as the corresponding functions computed in the usual N-vector/Ising model. The emergence of a critical vector order parameter in the gauge model shows the complete equivalence of the O(N)*/Ising* and O(N)/Ising universality classes.
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