Quantum entanglement and Einstein-Podolsky-Rosen steering in magnon frequency comb

TL;DR

This paper theoretically explores the quantum properties of magnon frequency combs, demonstrating entanglement and EPR steering between different comb teeth, highlighting their potential for quantum information and metrology.

Contribution

It is the first to analyze quantum fluctuations and demonstrate entanglement and EPR steering in magnon frequency combs within a hybrid magnon-skyrmion system.

Findings

Strong two-mode squeezed entanglement observed

Asymmetric EPR steering between magnon teeth

Skyrmion acts as an effective reservoir for cooling

Abstract

Significant progress has been made for the emerging concept of magnon frequency comb (MFC) but mainly in the classical region. The quantum property of the comb structure is yet to be explored. Here we theoretically investigate the quantum fluctuations of frequency combs and demonstrate the continuous-variable quantum entanglement and Einstein-Podolsky-Rosen (EPR) steering between different teeth of MFC. Without loss of generality, we address this issue in a hybrid magnon-skyrmion system. We observe a strong two-mode squeezed entanglement and asymmetric steering between the sum- and difference-frequency magnon teeth mediated by the skyrmion that acts as an effective reservoir to cool the Bogoliubov mode delocalized over the first-order magnon pair in MFC. Our findings show the prominent quantum nature of MFC, which has the potential to be utilized in ultrafast quantum metrology and multi-task quantum information processing.