Self-Organized Error Correction in Random Unitary Circuits with Measurement

Abstract

Random measurements have been shown to induce a phase transition in an extended quantum system evolving under chaotic unitary dynamics, when the strength of measurements exceeds a threshold value. Below this threshold, a steady state with a sub-thermal volume law entanglement emerges, which is resistant to the disentangling action of measurements, suggesting a connection to quantum error-correcting codes. Here we quantify these notions by identifying a universal, subleading logarithmic contribution to the volume law entanglement entropy: S(2)(A)= LA+32 LA which bounds the mutual information between a qudit inside region A and the rest of the system. Specifically, we find the power law decay of the mutual information I(\x\:A) x-3/2 with distance x from the region's boundary, which implies that measuring a qudit deep inside A will have negligible effect on the entanglement of A. We obtain these results by mapping the entanglement dynamics to the imaginary time evolution of an Ising model, to which we can apply field-theoretic and matrix-product-state techniques. Finally, exploiting the error-correction viewpoint, we assume that the volume-law state is an encoding of a Page state in a quantum error-correcting code to obtain a bound on the critical measurement strength pc as a function of the qudit dimension d: pc[(d2-1)(pc-1-1)] [(1-pc)d]. The bound is saturated at pc(d→∞)=1/2 and provides a reasonable estimate for the qubit transition: pc(d=2) 0.1893.