Super-Hawking radiation

Abstract: We discuss modifications to the Hawking spectrum that arise when the asymptotic states are supertranslated or superrotated. For supertranslations we find nontrivial off-diagonal phases in the two-point correlator although the emission spectrum is eventually left unchanged, as previously pointed out in the literature. In contrast, superrotations give rise to modifications which manifest themselves in the emission spectrum and depend nontrivially on the associated conformal factor at future null infinity. We stu… Show more

“…Hence the Unruh radiation spectrum is left invariant under these shockwaves -only excited states directly see the effect of the profile. Similar results were also obtained for Hawking radiation, see [35].…”

“…In this paper we show that, contrary to the conclusions of [33][34][35], a gravitational shockwave does leave a quantum imprint on the vacuum state of a test quantum scalar field, and, this imprint is accessible to local observers carrying UDW detectors in the shockwave spacetime. Namely, we show that the Wightman function contains an additional term that depends on the shockwave profile and that this term is nonzero between two spacetime events that are located on different sides of the shockwave null plane.…”

“…In summary, the studies [33][34][35] have reached the same conclusion: for asymptotic vacua both Unruh and Hawking spectra are unchanged by the presence of gravitational shockwaves, and, while gravitational shockwaves can leave imprints on test quantum fields, this will only happen for non-vacuum states. It is the purpose of the present paper to refute this last conclusion.…”

“…Similar questions have been investigated by a number of recent studies [32][33][34][35]. Our work is mainly motivated by [33,34] where the authors studied the impact of a 'matter induced' supertranslation on the Bogoliubov coefficients between the two asymptotic states.…”

“…However, since there is no localized number operator that agrees with the global number operator for the vacuum state, the Bogoliubov coefficients are arguably not a true local observable in this context, a result deeply connected to the Reeh-Schlieder theorem, see [36][37][38][39][40][41] for further discussions. Therefore, the results obtained in [32,33,35] are global results that no localized observers can easily access. The method employed in [34] is more suitable for local calculations, since it relies on a computation of the Wightman function of the quantum field on the shockwave background, which is known to be accessible to local observers, e.g.…”

Quantum imprints of gravitational shockwaves

“…Hence the Unruh radiation spectrum is left invariant under these shockwaves -only excited states directly see the effect of the profile. Similar results were also obtained for Hawking radiation, see [35].…”

“…In this paper we show that, contrary to the conclusions of [33][34][35], a gravitational shockwave does leave a quantum imprint on the vacuum state of a test quantum scalar field, and, this imprint is accessible to local observers carrying UDW detectors in the shockwave spacetime. Namely, we show that the Wightman function contains an additional term that depends on the shockwave profile and that this term is nonzero between two spacetime events that are located on different sides of the shockwave null plane.…”

“…In summary, the studies [33][34][35] have reached the same conclusion: for asymptotic vacua both Unruh and Hawking spectra are unchanged by the presence of gravitational shockwaves, and, while gravitational shockwaves can leave imprints on test quantum fields, this will only happen for non-vacuum states. It is the purpose of the present paper to refute this last conclusion.…”

“…Similar questions have been investigated by a number of recent studies [32][33][34][35]. Our work is mainly motivated by [33,34] where the authors studied the impact of a 'matter induced' supertranslation on the Bogoliubov coefficients between the two asymptotic states.…”

“…However, since there is no localized number operator that agrees with the global number operator for the vacuum state, the Bogoliubov coefficients are arguably not a true local observable in this context, a result deeply connected to the Reeh-Schlieder theorem, see [36][37][38][39][40][41] for further discussions. Therefore, the results obtained in [32,33,35] are global results that no localized observers can easily access. The method employed in [34] is more suitable for local calculations, since it relies on a computation of the Wightman function of the quantum field on the shockwave background, which is known to be accessible to local observers, e.g.…”

Quantum imprints of gravitational shockwaves

The SAGEX review on scattering amplitudes Chapter 11: Soft Theorems and Celestial Amplitudes

Energetics of a self-gravitating quantum system of charged particles