Distance between two manifolds, topological phase transitions and scaling laws

TL;DR

This paper introduces a universal manifold distance measure based on fidelity and trace distance to analyze topological phase transitions, applicable across various models and revealing critical behaviors.

Contribution

It proposes a novel, model-independent topological invariant using quantum information concepts that captures phase transitions without relying on geometric phases.

Findings

Distance and derivatives smoothly transition for identical manifolds.

Higher-order derivatives diverge near critical points.

Method applicable to diverse topological systems.

Abstract

Topological phases are generally characterized by topological invariants denoted by integer numbers. However, different topological systems often require different topological invariants to measure, such as geometric phases, topological orders, winding numbers, etc. Moreover, geometric phases and its associated definitions usually fail at critical points. Therefore, it's challenging to predict what would occur during the transformation between two different topological phases. To address these issues, in this work, we propose a general definition based on fidelity and trace distance from quantum information theory: manifold distance. This definition does not rely on the berry connection of the manifolds but rather on the information of the two manifolds - their ground state wave functions. Thus, it can measure different topological systems (including traditional band topology models, non-Hermitian systems, and topological order models, etc.) and exhibit some universal laws during the transformation between two topological phases. Our research demonstrates that when the properties of two manifolds are identical, the distance and associated higher-order derivatives between them can smoothly transition to each other. However, for two different topological manifolds, the higher-order derivatives exhibit various divergent behaviors near the critical points. For subsequent studies, we expect the method to be generalized to real-space or non-lattice models, in order to facilitate the study of a wider range of physical platforms such as open systems and many-body localization.