Splitting instability of a doubly quantized vortex in homogeneous superfluids
ORAL
Abstract
We revisit the fundamental problem of splitting instability of a doubly-quantized
vortex in uniform single-component superfluids at zero temperature. We analyze
the system-size dependence of the excitation frequency of a doubly-quantized
vortex through large-scale simulations of the Bogoliubov–de Gennes equation,
finding that the system remains dynamically unstable even in the
infinite-system-size limit. The perturbation and semi-classical analyses reveal
that the splitting instability radiates a damped oscillatory phonon as a
counterpart of a quasi-normal mode.
vortex in uniform single-component superfluids at zero temperature. We analyze
the system-size dependence of the excitation frequency of a doubly-quantized
vortex through large-scale simulations of the Bogoliubov–de Gennes equation,
finding that the system remains dynamically unstable even in the
infinite-system-size limit. The perturbation and semi-classical analyses reveal
that the splitting instability radiates a damped oscillatory phonon as a
counterpart of a quasi-normal mode.
*This work was supported by KAKENHI from the JSPS (Grants No. 17K05549, 17H02938, 26870295,
26400371) and also supported in part by the OCU Strategic Research Grant 2017 for young researchers.
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Presenters
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Kenichi Kasamatsu
- Department of physics, Kindai Univ