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Main Authors: Headley, Francis J., Müller, Fabian, Köse, Emre, Fuchs, Tim, Ulbricht, Hendrik, Braun, Daniel
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.19125
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author Headley, Francis J.
Müller, Fabian
Köse, Emre
Fuchs, Tim
Ulbricht, Hendrik
Braun, Daniel
author_facet Headley, Francis J.
Müller, Fabian
Köse, Emre
Fuchs, Tim
Ulbricht, Hendrik
Braun, Daniel
contents We study the quantum dynamics of the rotational degree of freedom of a nano-magnet trapped in a superconducting trap. The nano-magnet is modeled as a magnetic dipole with magnetization pinned to the easy axis of the particle. The magnetic trap then leads to a potential barrier that hinders free rotation of the particle, but through which it can tunnel. We identified rest-gas scattering as the most important decoherence mechanism at low temperatures. A shape of the particle sufficiently close to perfect rotational symmetry about the rotational axis can protect the rotational tunneling against this decoherence mechanism, and we identify experimentally feasible parameter regimes where rotational tunneling should be observable.
format Preprint
id arxiv_https___arxiv_org_abs_2605_19125
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Rotational Quantum Tunneling of a Magnetic Dipole in a Superconducting Trap
Headley, Francis J.
Müller, Fabian
Köse, Emre
Fuchs, Tim
Ulbricht, Hendrik
Braun, Daniel
Quantum Physics
We study the quantum dynamics of the rotational degree of freedom of a nano-magnet trapped in a superconducting trap. The nano-magnet is modeled as a magnetic dipole with magnetization pinned to the easy axis of the particle. The magnetic trap then leads to a potential barrier that hinders free rotation of the particle, but through which it can tunnel. We identified rest-gas scattering as the most important decoherence mechanism at low temperatures. A shape of the particle sufficiently close to perfect rotational symmetry about the rotational axis can protect the rotational tunneling against this decoherence mechanism, and we identify experimentally feasible parameter regimes where rotational tunneling should be observable.
title Rotational Quantum Tunneling of a Magnetic Dipole in a Superconducting Trap
topic Quantum Physics
url https://arxiv.org/abs/2605.19125