Cherenkov emission by a fast-moving uncharged Schwarzschild black hole

Abstract

We demonstrate that, in the presence of an external magnetic field, an uncharged classical Schwarzschild black hole moving superluminally in a dielectric with permittivity ε > 1 produces Cherenkov emission. This is a new physical effect: classical (non-quantum) emission of electromagnetic waves by a completely charge-neutral ``particle.'' The governing equations (involving general relativity, electromagnetism, and the physics of continuous media) have no external electromagnetic source -- it is the distortion of the initial electromagnetic fields by the gravity of the black hole that plays the role of a superluminally moving source. The effect relies on nonzero values of both the magnetic field and the gravitational radius, as well as on the usual Cherenkov condition on the velocity, v/c > 1/ε. Unlike Cherenkov emission by a point charge, the effective source in this case is spatially distributed, with emission generated along the single Cherenkov emission cone. The emitted spectrum is red-dominated, with power dkz /|kz| for wave numbers |kz| ≤ 1/RG, where RG is the Schwarzschild radius. We comment on possible observability of this process during black hole -- neutron star mergers.

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