The Levitron is a toy that consists of a spinning top that levitates over a magnetic base for a few minutes, until air drag decreases the spin rate below a certain limit. Stable levitation, lasting hours or even days, has been achieved for Levitrons that were externally driven by either an air jet or an alternating magnetic field. We report measurements of stable levitation for the latter case. We show that the top precession couples with the frequency of the alternating field, so that the precession period equals the period of the field. In addition, the top rotates around itself with the same period. We present numerical simulations that reproduce the essential features of this dynamics. It is also shown that the magnetic torque that drives the top is due to a misalignment between the magnetic dipole moment and the mechanical axis of the top.

Topics
Electromagnetism, Magnetic dipole moment, Magnetic fields, Rotational dynamics, Torque, Helmholtz coil, MATLAB, Magnetic properties, Educational aids, Educational assessment
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See supplementary material at http://dx.doi.org/10.1119/1.4895800 for six videos, three showing experimental observations and three showing numerical simulations.
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© 2015 American Association of Physics Teachers.
2015
American Association of Physics Teachers

Supplementary Material

Supplementary Material- zip file
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