Timelike Entanglement Entropy and Renormalization Group Flow Irreversibility
Authors
Dimitrios Giataganas
Abstract
We study holographic c-theorems based on timelike entanglement entropy and show that a timelike c-function captures irreversible renormalization group (RG) flow. We demonstrate that timelike c-functions are applicable to both relativistic and non-relativistic quantum matter in nematic phases with broken rotational symmetry, and that they remain monotonic even under anisotropic RG flows, thereby passing some of the most stringent consistency tests. Across all classes of theories examined, we find that the null energy condition, thermodynamic stability, and a constraint on an effective spatial dimensionality are jointly sufficient to guarantee monotonicity of the timelike c-function along the RG flow. Moreover, we identify a geometric upper bound on the rate of change of the timelike c-function, which constrains how rapidly effective degrees of freedom can be coarse-grained along the RG flow whenever a timelike c-theorem applies. The applicability of holographic c-theorems is thus extended to highly nontrivial RG flows and points toward a new information-theoretic diagnostic of holographic RG dynamics.
