Superactivation of Bell nonlocality in pure anyonic states

TL;DR

This paper explores how certain pure anyonic states, despite being local individually, can exhibit nonlocality through collective measurements, revealing a superactivation phenomenon unique to anyonic quantum systems.

Contribution

It demonstrates superactivation of Bell nonlocality in pure anyonic states and analyzes the entanglement components responsible for this effect, providing new insights into anyonic quantum correlations.

Findings

Pure anyonic states with non-zero AEE can be local yet nonlocal under collective measurements.

Entanglement related to tensor product structure correlates with nonlocality.

Superactivation of nonlocality occurs in pure anyonic states, unlike in conventional systems.

Abstract

Standard quantum information theory is founded on the assumption that multi-party state space possesses a tensor product structure. Anyons, as quasiparticles in two-dimensional systems, exhibit unique entanglement properties that differ from the conventional quantum systems, resulting from the absence of a tensor product structure in their state spaces. This motivates us to investigate the relationship between Bell nonlocality and entanglement in anyonic states. Specifically, we find that certain pure anyonic states with non-zero anyonic entanglement entropy (AEE) are local, yet exhibit nonlocality when subjected to collective measurements on multiple copies-a phenomenon known as superactivation of nonlocality, which is typically observed in conventional mixed states. To analyze this, we decompose the total entanglement of anyonic states into two components: one from the tensor product structure and the other representing residual contributions. By studying their asymptotic behavior, we find that the former gradually increases and approaches the AEE while the latter diminishes with the number of copies. Crucially, the entanglement component associated with the tensor product structure demonstrates a significant correlation with nonlocality, which explains the observed superactivation of nonlocality. Our findings provide new insights into the connection between entanglement and nonlocality in anyonic systems.