Quantum error as an emergent magnetic field
Abstract
We investigate the effect of quantum errors on a monitored Brownian Sachdev-Ye-Kitaev (SYK) model featuring a measurement-induced phase transition that can be understood as a symmetry-breaking transition of an effective magnet in the replica space. The errors describe the loss of information about the measurement outcomes and are applied during the non-unitary evolution or at the end of the evolution. In the former case, we find that this error can be mapped to an emergent magnetic field in the magnet, and as a consequence, the symmetry is explicitly broken independent of the measurement rate. R\'enyi entropies computed by twisting boundary conditions now generate domain walls even in the would-be symmetric phase at a high measurement rate. The entropy is therefore volume-law irrespective of the measurement rate. In the latter case, the error-induced magnetic field only exists near the boundary of the magnet. Varying the magnetic field leads to a pinning transition of domain walls, corresponding to error threshold of the quantum code prepared by the non-unitary SYK dynamics.
Cite
@article{arxiv.2106.09635,
title = {Quantum error as an emergent magnetic field},
author = {Shao-Kai Jian and Chunxiao Liu and Xiao Chen and Brian Swingle and Pengfei Zhang},
journal= {arXiv preprint arXiv:2106.09635},
year = {2021}
}
Comments
4.4 pages + supplemental material, 4 figures