Tripartite high-dimensional magnon-photon entanglement in PT -symmetry
broken phases of a non-Hermitian hybrid system
- URL: http://arxiv.org/abs/2206.12769v1
- Date: Sun, 26 Jun 2022 02:39:16 GMT
- Title: Tripartite high-dimensional magnon-photon entanglement in PT -symmetry
broken phases of a non-Hermitian hybrid system
- Authors: Jin-Xuan Han and Jin-Lei Wu1and Yan Wang and Yan Xia and Yong-Yuan
Jiang and and Jie Song
- Abstract summary: Tripartite high-dimensional entangled states can be generated steadily among modes of the magnon and photons in PT -symmetry broken phases.
This work may provide prospects for realizing multipartite high-dimensional entangled states in the magnon-circuit-QED hybrid system.
- Score: 11.13464273942407
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Hybrid systems that combine spin ensembles and superconducting circuits
provide a promising platform for implementing quantum information processing.
We propose a non-Hermitian magnoncircuit-QED hybrid model consisting of two
cavities and an yttrium iron garnet (YIG) sphere placed in one of the cavities.
Abundant exceptional points (EPs), parity-time (PT )-symmetry phases and PT
-symmetry broken phases are investigated in the parameter space. Tripartite
highdimensional entangled states can be generated steadily among modes of the
magnon and photons in PT -symmetry broken phases, corresponding to which the
stable quantum coherence exists. Results show that the tripartite
high-dimensional entangled state is robust against the dissipation of hybrid
system, independent of a certain initial state, and insensitive to the
fluctuation of magnonphoton coupling. Further, we propose to simulate the
hybrid model with an equivalent LCR circuit. This work may provide prospects
for realizing multipartite high-dimensional entangled states in the
magnon-circuit-QED hybrid system.
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