How to access QED at supercritical Coulomb field

TL;DR

This paper investigates how positron energy spectra can reveal the transition from subcritical to supercritical regimes in nuclear collisions, providing clearer evidence of spontaneous vacuum decay and extending analysis to collisions involving neutral atoms.

Contribution

It advances previous work by calculating positron spectra and identifying signatures of supercritical vacuum decay, and explores collisions with neutral atoms for observable effects.

Findings

Positron spectra show clear signatures of the supercritical transition.

Focusing on specific energy regions enhances evidence of vacuum decay.

Collisions of uranium with neutral atoms have high probabilities for observing vacuum decay.

Abstract

In slow collisions of two bare nuclei with the total charge number larger than the critical value, $Z_{\rm cr} \approx 173$, the initially neutral vacuum can spontaneously decay into the charged vacuum and two positrons. Detection of the spontaneous emission of positrons would be the direct evidence of this fundamental phenomenon. However, the spontaneous emission is generally masked by the dynamical positron emission, which is induced by a strong time-dependent electric field created by the colliding nuclei. In our recent paper [I.A. Maltsev et al., Phys. Rev. Lett. 123, 113401 (2019)] it has been shown that the spontaneous pair production can be observed via measurements of the pair-production probabilities for a given set of nuclear trajectories. In the present paper, we have significantly advanced this study by exploring additional aspects of the process we are interested in. We calculate the positron energy spectra and find that these spectra can give a clear signature of the transition from the subcritical to the supercritical regime. It is found that focusing on a part of the positron spectrum, which accounts for the energy region where the spontaneously created positrons can contribute, allows to get a much stronger evidence of the transition to the supercritical mode, making it very well pronounced in collisions, for example, of two uranium nuclei. The possibility of extending this study to collisions of bare nuclei with neutral atoms is also considered. The probability of a vacancy in the lowest-energy state of a quasimolecule which is formed in collisions of a bare U nucleus with neutral U and Cm atoms has been calculated. The relatively large values of this probability make such collisions suitable for observing the vacuum decay.