Magnetic levitation within a microwave cavity: characterization,
challenges, and possibilities
- URL: http://arxiv.org/abs/2208.03220v1
- Date: Mon, 4 Jul 2022 20:13:54 GMT
- Title: Magnetic levitation within a microwave cavity: characterization,
challenges, and possibilities
- Authors: Nabin K. Raut, Jeffery Miller, Raymond E. Chiao, and Jay E. Sharping
- Abstract summary: Low energy losses in superconducting magnetic levitation make it attractive for exciting applications in physics.
Meissner levitation within the microwave cavity could open avenues for the novel cavity optomechanical system.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: The low energy losses in the superconducting magnetic levitation make it
attractive for exciting applications in physics. Recently, superconducting
magnetic levitation has been realized as novel mechanical transduction for the
individual spin qubit in the nitrogen-vacancy center [1]. Furthermore, the
Meissner has been proposed for the study of modified gravitational wave
detection [2]. Meissner levitation within the microwave cavity could open
avenues for the novel cavity optomechanical system, readout for quantum object
such as the transmon, and magnon, gravitational wave detection, and
magnetomechanics [3]. This work characterized magnetic levitation within a
microwave. It also discusses possibilities, challenges, and room temperature
and cryogenic experiments of the cavity-magnet system.
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