Statistical Mechanics of Monitored Random Quantum Circuits

The central philosophy of statistical mechanics and random-matrix theory of complex systems is that while individual instances are essentially intractable to simulate, the statistical properties of random ensembles obey simple universal "laws". This same philosophy promises powerful methods for studying the dynamics of quantum information in ideal and noisy quantum circuits – for which a classical simulation of individual circuits is expected to be generically intractable. In this talk, I will review recent progress in understanding the dynamics of quantum information in ensembles of random monitored quantum circuits through a statistical mechanics lens. In particular, I will describe applications of this formalism to the measurement-induced phase transitions that separate phases characterized by the amount of quantum information that can be extracted from measurements.