http://arxiv.org/abs/2212.09784
In the cosmological settings, Quantum Gravity effects are typically understood to be limited towards very early phase of the universe, namely in the pre-inflationary era, with limited signatures remaining present in the succeeding inflationary era. These signatures also gradually fade away as the universe grows and exits the inflationary era. In the subsequent radiation and matter dominated era quantum gravity is expected to play no significant role. Classicalized primordial perturbations such as the scalar perturbations and the gravitational waves are expected to leave an imprint on CMB anisotropy and its polarization respectively but quantized gravitational waves are not expected to lead to any appreciable observable effects. Apart from cosmology, in other avenues as well, the imprints of quantum character of gravitational waves are typically so subdued that any possible signature gets buried under a huge pile of the noise or effects from other much stronger processes. In this work, we demonstrate that quantum gravity perturbations cause strong observable effects in cosmological settings post the Last Scattering Surface (LSS) more prominently than any other classical or quantum processes. This counter-intuitive effect is facilitated by the fact that the correlators of the gravitational waves {\it grow divergently large in the matter dominated era} unlike any other background fields, leading to an abrupt rise in the processes mediated by correlators of quantum gravitons. The transitions between spherical harmonics states of newly formed hydrogen atom at the LSS, when the universe resides in strong matter dominated era, provides an example of such a process. We further establish that the late time epoch just before the kicking in of the dark energy provides one of the cleanest avenues to study such quantum gravity effects.
A. Dhanuka and K. Lochan
Wed, 21 Dec 22
6/81
Comments: 12 pages, 1 Figure