Rényi and Shannon mutual information in critical and decohered critical system

Abstract: We investigate a critical many-body system by introducing a R\'{e}nyi generalized mutual information, connecting between R\'{e}nyi mutual information and R\'{e}nyi Shannon mutual information. This R\'{e}nyi generalized mutual information can offer more experimentally accessible alternative than the conventional entanglement entropy. As a critical many-body state, we focus on the critical transverse-field Ising model (TFIM) described by the Ising conformal field theory (CFT). We show that even if we modify the non-selective projective measurement assumed in R\'{e}nyi Shannon mutual information by replacing the measurement into decoherence by environment, the R\'{e}nyi generalized Shannon mutual information maintains the CFT properties such as subsystem CFT scaling law and its central charge observed through both the conventional R\'{e}nyi Shannon mutual information and R\'{e}nyi mutual information. Furthermore, we apply a local decoherence to the critical ground state of the TFIM and numerically observe the R\'{e}nyi generalized mutual information by changing the parameter controlling environment effect (corresponding to the strength of measurement) in the R\'{e}nyi generalized mutual information and the strength of the decoherence to which the entire system subjects. We find that R\'{e}nyi-$2$ type central charge connected to the central charge is fairly robust, indicating the strong robustness of the Ising CFT properties against local decoherence by environment.