Quantum-Squeezing-Induced Point-Gap Topology and Skin Effect

Abstract

We theoretically predict the squeezing-induced point-gap topology together with a symmetry-protected Z2 skin effect in a one-dimensional (1D) quadratic-bosonic system (QBS). Protected by a time-reversal symmetry, such a topology is associated with a novel Z2 invariant (similar to quantum spin-Hall insulators), which is fully capable of characterizing the occurrence of Z2 skin effect. Focusing on zero energy, the parameter regime of this skin effect in the phase diagram just corresponds to a real-gap and point-gap coexisted topological phase. Moreover, this phase associated with the symmetry-protected Z2 skin effect is experimentally observable by detecting the steady-state power spectral density. Our work is of fundamental interest in enriching non-Bloch topological physics by introducing quantum squeezing, and has potential applications for the engineering of symmetry-protected sensors based on the Z2 skin effect.