Noise-tolerant Detection of ZN Topological Orders in Quantum Many-body States

Abstract

Topologically ordered states are fundamentally important in theoretical physics, which are also suggested as promising candidates to build fault-tolerant quantum devices. However, it is still elusive how topological orders can be affected or detected under noises. In this work, we find a quantity, termed as the ring degeneracy D, which is robust under pure noise to detect both trivial and intrinsic topological orders. The ring degeneracy is defined as the degeneracy of the solutions of the self-consistent equations that encode the contraction of the corresponding tensor network(TN). For the ZN orders, we find that the ring degeneracy satisfies a simple relation D = (N + 1)/2 + d, with d = 0 for odd N and d = 1/2 for even N. Simulations on several non-trivial states (two-dimensional Ising model, ZN topological states, and resonating valence bond states) show that the ring degeneracy can tolerate noises up to a strength associated to the gap of the TN boundary theory.