Symmetry-protected quantization of complex Berry phases in non-Hermitian many-body systems

Abstract

We investigate the quantization of the complex-valued Berry phases in non-Hermitian quantum systems with certain generalized symmetries. In Hermitian quantum systems, the real-valued Berry phase is known to be quantized in the presence of certain symmetries, and this quantized Berry phase can be regarded as a topological order parameter for gapped quantum systems. In this paper, on the other hand, we establish that the complex Berry phase is also quantized in the systems described by a family of non-Hermitian Hamiltonians. Let H(θ) be a non-Hermitian Hamiltonian parameterized by θ. Suppose that there exists a unitary and Hermitian operator P such that PH(θ)P = H(-θ) or PH(θ)P = H(-θ). We prove that in the former case, the complex Berry phase γ is Z2-quantized, while in the latter, only the real part of γ is Z2-quantized. The operator P can be viewed as a generalized symmetry for H(θ), and in practice, P can be, for example, a spatial inversion. We also argue that this quantized complex Berry phase is capable of classifying non-Hermitian topological phases, and we demonstrate this in some one-dimensional strongly correlated systems.