Shannon entropy of the measurement record at measurement-dominated criticality and RG flow: A c-theorem for effective central charge and a g-theorem for effective boundary entropy

Abstract

We present two theorems demonstrating non-perturbatively the decrease under relevant renormalization group (RG) flow of two quantities, ceff and geff characterizing, respectively, the universal information content of the Shannon entropy of the measurement record for two different types of measurement-dominated criticality. First, we demonstrate the decrease of the "effective central charge" ceff of 2D replica field theories in the R→1 replica limit that govern the long-distance physics of weakly monitored 2D classical critical systems (Baysian inference problems) studied recently in the literature [arXiv:2504.01264; arXiv:2504.12385; arXiv:2504.08888]. In particular, we show that ceff is less than the central charge c of the unmeasured critical system. We refer to this result as the "c-effective theorem''. In addition, we present an analogous "g-effective theorem" demonstrating the decrease under RG flow of the effective "Affleck-Ludwig'' boundary entropy geff, quantifying a corresponding contribution to the Shannon entropy for analogous 2D defect replica field theories in the R→1 replica limit, which govern the long-distance physics in the problem of performing weak quantum measurements on one-dimensional quantum critical ground states. Lastly, we discuss a possible consequence of our theorems for classical systems with generic uncorrelated impurity-type quenched disorder, according to which, under a certain assumption, and as opposed to problems with measurement-induced randomness, the corresponding universal quantities ceff(R→0) and geff(R→0) in the R→0 replica limit would increase under RG flow.