Abstract
Mid-circuit measurements and feedback operations conditioned on their outcomes are essential primitives for realizing quantum error correction on modern quantum hardware. When incorporated into quantum many-body dynamics, these non-unitary operations can drive novel non-equilibrium phase transitions—both in the dynamics of individual quantum trajectories and in the ensemble-averaged quantum channel. The well-known measurement-induced entanglement transition belongs to the former category. In this talk, I will introduce a class of adaptive random-circuit models with feedback that exhibit phase transitions in both settings. By mapping the feedback-driven dynamics to classical stochastic processes, we show that the resulting absorbing-state transition falls into either the parity-conserving or directed-percolation universality class, depending on the feedback protocol. In the second part, I will present experimental results from a superconducting quantum processor featuring high-fidelity mid-circuit measurements and low-latency conditional feedback, where we directly observe the coexistence of measurement-induced entanglement and absorbing-state transitions.
Zhi-Cheng Yang is an assistant professor at School of Physics, Peking University. He received B.S. in physics from Peking University in 2013, and Ph.D. in physics from Boston University in 2019, supervised by Claudio Chamon. He then moved to University of Maryland College Park as a Postdoctoral Researcher, before joining the current position in 2022.