Magnon-magnon entanglement and its detection in a microwave cavity
- URL: http://arxiv.org/abs/2106.06862v1
- Date: Sat, 12 Jun 2021 20:46:55 GMT
- Title: Magnon-magnon entanglement and its detection in a microwave cavity
- Authors: Vahid Azimi Mousolou, Yuefei Liu, Anders Bergman, Anna Delin, Olle
Eriksson, Manuel Pereiro, Danny Thonig and Erik Sj\"oqvist
- Abstract summary: Quantum magnonics is an emerging research field with great potential for applications in quantum information processing.
We investigate antiferromagnets in which sublattices with ferromagnetic interactions can have two different magnon modes.
We show how this may lead to experimentally detectable bipartite continuous variable magnon-magnon entanglement.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Quantum magnonics is an emerging research field, with great potential for
applications in magnon based hybrid systems and quantum information processing.
Quantum correlation, such as entanglement, is a central resource in many
quantum information protocols that naturally comes about in any study toward
quantum technologies. This applies also to quantum magnonics. Here, we
investigate antiferromagnets in which sublattices with ferromagnetic
interactions can have two different magnon modes, and we show how this may lead
to experimentally detectable bipartite continuous variable magnon-magnon
entanglement. The entanglement can be fully characterized via a single
squeezing parameter, or, equivalently, entanglement parameter. The clear
relation between the entanglement parameter and the Einstein, Podolsky, and
Rosen (EPR) function of the ground state opens up for experimental observation
of magnon-magnon continuous variable entanglement and EPR non-locality. We
propose a practical experimental realization to detect the EPR function of the
ground state, in a setting that relies on magnon-photon interaction in a
microwave cavity.
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