Litcius/Paper detail

Cavity magnomechanical storage and retrieval of quantum states

Bijita Sarma, Thomas Busch, Jason Twamley

2021New Journal of Physics63 citationsDOIOpen Access PDF

Abstract

Abstract We show how a quantum state in a microwave cavity mode can be transferred to and stored in a phononic mode via an intermediate magnon mode in a magnomechanical system. For this we consider a ferrimagnetic yttrium iron garnet (YIG) sphere inserted in a microwave cavity, where the microwave and magnon modes are coupled via a magnetic-dipole interaction and the magnon and phonon modes in the YIG sphere are coupled via magnetostrictive forces. By modulating the cavity and magnon detunings and the driving of the magnon mode in time, a stimulated Raman adiabatic passage-like coherent transfer becomes possible between the cavity mode and the phonon mode. The phononic mode can be used to store the photonic quantum state for long periods as it possesses lower damping than the photonic and magnon modes. Thus our proposed scheme offers a possibility of using magnomechanical systems as quantum memory for photonic quantum information.

Topics & Concepts

PhysicsMagnonStimulated Raman adiabatic passageYttrium iron garnetDegenerate energy levelsQuantumAdiabatic processCondensed matter physicsMicrowave cavityMicrowavePhononQuantum stateQuantum informationCavity quantum electrodynamicsPhotonicsSqueezed coherent stateRaman spectroscopyCoherent statesQuantum mechanicsQuantum opticsDissipationQuantum technologyGround stateBound stateOptical cavityPhotonic crystalQuantum information scienceOptoelectronicsQuantum computerMode (computer interface)FerrimagnetismQuantum simulatorQuantum networkQuantum dotMechanical and Optical ResonatorsQuantum optics and atomic interactionsTopological Materials and Phenomena