Bulk-edge correspondence in nonunitary Floquet systems with chiral symmetry
Ken Mochizuki, Dakyeong Kim, Norio Kawakami, Hideaki Obuse
Abstract
We study topological phases in one-dimensional open Floquet systems driven by chiral symmetric nonunitary time evolution. We derive a procedure to calculate topological numbers from nonunitary time-evolution operators with chiral symmetry. While the procedure has been applied to open Floquet systems described by nonunitary time-evolution operators, we give the microscopic foundation and clarify its validity. We construct a model of chiral symmetric nonunitary quantum walks classified into class ${\mathrm{BDI}}^{\ifmmode\dagger\else\textdagger\fi{}}$ or AIII, which is one of the enlarged symmetry classes for topological phases in open systems based on experiments of discrete-time quantum walks. Then we confirm that the topological numbers obtained from the derived procedure give correct predictions of the emergent edge states. We also show that the model retains $\mathcal{PT}$ symmetry in certain cases, and its dynamics is crucially affected by the presence or absence of $\mathcal{PT}$ symmetry.