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Ultralow Mechanical Damping with Meissner-Levitated Ferromagnetic Microparticles

A. Vinante, P. Falferi, G. Gasbarri, A. Setter, C. Timberlake, H. Ulbricht

2020Physical Review Applied81 citationsDOIOpen Access PDF

Abstract

Levitation of magnetic or superconducting microparticles is a promising technology for applications such as ultrasensitive force and gravity sensors, and experiments in fundamental and quantum physics. Unfortunately, achieving very low dissipation has proven to be more difficult than expected. This study demonstrates levitation of micromagnets by the Meissner effect above type-I superconductors, with very long damping times beyond 10${}^{4}$ s and quality factors exceeding 10${}^{7}$. The authors furthermore investigate using a levitated micromagnet as an ultrasensitive magnetometer, pointing out the potential for magnetic-field resolution beyond the current state of the art.

Topics & Concepts

LevitationMagnetic levitationDissipationMeissner effectSuperconductivityCondensed matter physicsMaterials scienceFerromagnetismMagnetic dampingCurrent (fluid)QuantumMagnetic fieldQuality (philosophy)Electrodynamic suspensionPhysicsQuantum dotHysteresisFerrofluidMechanical and Optical ResonatorsCharacterization and Applications of Magnetic NanoparticlesNonlocal and gradient elasticity in micro/nano structures
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