2020
DOI: 10.48550/arxiv.2009.06580
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Near-horizon aspects of acceleration radiation by free fall of an atom into a black hole

H. E. Camblong,
A. Chakraborty,
C. R. Ordonez

Abstract: A two-level atom freely falling towards a Schwarzschild black hole was recently shown to detect radiation in the Boulware vacuum in an insightful paper [M. O. Scully et al., PNAS 115(32), 8131 (2018)]. The two-state atom acts as a dipole detector and its interaction with the field can be modeled using a quantum optics approach. The relative acceleration between the scalar field and the detector causes the atom to detect the radiation. In this paper, we show that this acceleration radiation is driven by the n… Show more

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“…As we have already obtained the energy solution with the negative sign corresponds to the ingoing particle, therefore consequently we can tell that the energy solution with the positive sign corresponds to the outgoing particle. However, in this case we want to affirm that this energy solution of the outgoing particle exactly matches with the energy solution which we obtained earlier (39) with the knowledge of the outgoing particle trajectory (15). From the positive energy solution of (41), using Hamilton's equation of motion we obtain the radial equation of motion of the outgoing particle which is…”
Section: B Using Dispersion Relationsupporting
confidence: 76%
“…As we have already obtained the energy solution with the negative sign corresponds to the ingoing particle, therefore consequently we can tell that the energy solution with the positive sign corresponds to the outgoing particle. However, in this case we want to affirm that this energy solution of the outgoing particle exactly matches with the energy solution which we obtained earlier (39) with the knowledge of the outgoing particle trajectory (15). From the positive energy solution of (41), using Hamilton's equation of motion we obtain the radial equation of motion of the outgoing particle which is…”
Section: B Using Dispersion Relationsupporting
confidence: 76%