Acceleration radiation from vibrating atoms in Schwarzschild spacetime

Abstract

Motivated by the work of Scully et al. [ blueProc. Nat. Acad. Sci. 115, 8131 (2018)] and Dolan et al.[ blueNew J. Phys. 22, 033026 (2020)], we study the acceleration radiation from a two-level Unruh-DeWitt detector that undergoes small-amplitude radial oscillations at fixed mean radius R0 outside a Schwarzschild black hole. The massless scalar field is quantized in the Boulware vacuum to isolate curvature-modulated acceleration effects without a thermal Hawking background. Working in a (1+1) radial reduction and using first-order time-dependent perturbation, we evaluate the period-averaged transition rate (or the Floquet transition rate). The resulting particle emission spectrum exhibits a thermal Bose-Einstein-type profile with periodic trajectory yielding a Floquet resonance condition n > ω0 and a closed-form expression for the Floquet transition rate Pn, which reduces to the flat Minkowski spacetime result as R0∞, in agreement with Near the horizon, f(R0)<1 enhances the effective Bessel argument by 1/f(R0), providing a simple analytic demonstration of curvature/redshift amplification of acceleration radiation. In particular, the spectrum weighted by the Bessel function becomes ill-defined near the black hole horizon as R0→ 2M, possibly manifesting the well-known pathological behavior of the Boulware vacuum state. We discuss the regime of validity (small amplitude, R0 away from the horizon) and outline the extensions to (3+1) dimensions, including density-of-states and greybody factors, and to alternative vacuum choices. Our results offer an analytically tractable link between flat-space vibrating atom proposals and black-hole spacetimes.

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