Using a laser as a local detector of superfluid helium-4 surface modes, known as third sound waves, we propose an experiment to probe observer-dependence in detector response. By moving the interaction point along a circular trajectory, the response can be compared with its inertial counterpart. Disagreement between the two is a manifestation of the Unruh effect, predicting that the uniformly accelerated observer will experience a temperature in empty space. Third sound waves propagate in an effective spacetime, wherein the effect of acceleration is enhanced. Incorporating a nonzero ambient temperature, we identify an acceleration-dependent signal in the laser phase, and evaluate a signal-to-noise measure to show that observing this signal is within experimental reach.
We show that the dynamical instability of quantum vortices with more than a single quantum of angular momentum results from a superradiant bound state inside the vortex core. Our conclusion is supported by an analytic WKB calculation and numerical simulations of both linearised and fully non-linear equations of motion for a doubly-quantised vortex at the centre of a circular bucket trap. In the late stage of the instability, we reveal a striking novel behaviour of the system in the non-linear regime. Contrary to expectation, in the absence of dissipation the system never enters the regime of two well-separated phase defects described by Hamiltonian vortex dynamics. Instead, the separation between the two defects undergoes modulations which never exceed a few healing lengths, in which compressible kinetic energy and incompressible kinetic energy are exchanged. This suggests that, under the right conditions, pairs of vortices may be able to form meta-stable bound states.
Vortices and black holes set the scene for many interesting dynamical processes in physics. Here, we study the dynamical instability of quantised vortices and rotational superradiance around rotating black holes, illustrating in the process that the same physics is at play in these two seemingly disparate phenomena. We also compare the instability of the vortex to the black hole bomb instability, which occurs for massive scalar fields in the Kerr spacetime. Taking inspiration from the analogy between black hole bomb modes and the hydrogen spectrum, the vortex instability is compared with nuclear resonances involved in α-decay.
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