Monotonicity of renormalization group flow, Perelman's entropy functional, and emergent dual holography in the worldsheet nonlinear \(\sigma\) model

Based on the renormalization group (RG) flow of worldsheet bosonic string theory, we construct an effective holographic dual description, where an extra dimension is identified with an RG scale. As a result, we obtain a dilaton-gravity effective theory for the dynamics of an emergent target spacetime, analogous to the low-energy description of bosonic M theory. We argue that this holographic dual effective field theory is non-perturbative in nature for the \(\alpha'\) expansion, where the RG flow of the target spacetime manifests in the level of an effective bulk action. Based on the holographic dual effective field theory, we investigate the monotonicity of the RG flow. Inspired by the monotonicity of the Ricci flow given by Perelman, we propose a holographic construction of the Perelman's entropy functional. Based on the equivalence between the Hamilton-Jacobi equation and the local RG equation, we show that the RG flow of holographic Perelman's entropy functional is nothing but the Weyl anomaly. This leads us to the monotonicity of the RG flow of the emergent target spacetime. Furthermore, considering the entropy production along the RG flow, we construct a microscopic entropy functional based on the probability distribution function of the holographic dual effective field theory, regarded as Gibbs or Shannon entropy. We find that the monotonicity of this microscopically constructed entropy functional shows a strong connection with the monotonicity of the holographic Perelman's entropy functional.