Acceleration sensing with magnetically levitated oscillators above a superconductor

Abstract

We experimentally demonstrate stable trapping of a permanent magnet sphere above a lead superconductor, in vacuum pressures of 4 × 10-8~mbar. The levitating magnet behaves as a harmonic oscillator, with frequencies in the 4-31~Hz range detected, and shows promise to be an ultrasensitive acceleration sensor. We directly apply an acceleration to the magnet with a current carrying wire, which we use to measure a background noise of 10-10 \ m/Hz at 30.75~Hz frequency. With current experimental parameters, we find an acceleration sensitivity of Sa1/2 = 1.2 0.2 × 10-10 \ g/Hz, for a thermal noise limited system. By considering a 300~mK environment, at a background helium pressure of 1 × 10-10~mbar, acceleration sensitivities of Sa1/2 3 × 10-15 \ g/Hz could be possible with ideal conditions and vibration isolation. To feasibly measure with such a sensitivity, feedback cooling must be implemented.