Intensive Cavity-Magnomechanical Cooling of a Levitated Macromagnet
A. Kani, B. Sarma, J. Twamley
Abstract
We describe microwave cavity-magnomechanical center-of-mass cooling of a levitated magnetic sphere. The standing magnetic component of the electromagnetic wave within a microwave cavity exerts a dynamical force on a magnonic crystalline sphere and dissipates the mechanical energy through scattering into the magnon mode. The coupling is established by the magnetic dipole interaction and enriched by the collective spin motion. We find that the final cooled phonon occupation achieved is an intensive property independent of the mass and size of the sphere, in contrast to standard optomechanical couplings. This is of particular importance for testing quantum mechanics with macroscopic objects.
Topics & Concepts
PhysicsMagnonMicrowaveMagnetic levitationPhononCondensed matter physicsCoupling (piping)ScatteringSpin waveElectromagnetic radiationElectromagnetic suspensionMagnetic energyMicrowave cavityQuantumForce between magnetsDipoleRadiation pressureMagnetic momentMagnetic dipoleMagnetismMechanical energySpin (aerodynamics)Magnetic fieldClassical mechanicsStanding waveQuantum opticsInternal energyMechanical and Optical ResonatorsQuantum Electrodynamics and Casimir EffectMagnetic and Electromagnetic Effects