Generation of Primordial Black Holes and Gravitational Waves from Dilaton-Gauge Field Dynamics

TL;DR

This paper explores how a kinetically coupled gauge field during inflation can produce observable primordial black holes and gravitational waves, with unique signatures that future detectors could test.

Contribution

It introduces a model with a stabilized gauge kinetic function causing non-monotonic gauge field growth, leading to distinctive primordial black hole and gravitational wave predictions.

Findings

Predicts a bumpy curvature power spectrum shape.

Shows potential for primordial black holes as dark matter.

Suggests detectable gravitational wave signals from the model.

Abstract

We study the observational signatures from particle production of a $U(1)$ gauge field kinetically coupled to an inflaton. Regarding the form of gauge kinetic function, we consider the possibility that it becomes stabilized at a certain time, which makes the growing power of the gauge field evolve non-monotonically with a sharp transition. Remarkably, the copious production of the gauge field occurs on super-horizon scales at the late stage of inflation and perturbations are enhanced on the intermediate scales during inflation. We find that it can predict a bumpy shape of the curvature power spectrum which leads to the generation of primordial black holes as a dark matter after inflation. We also estimate two types of tensor modes sourced by the gauge field: the primordial gravitational waves generated during inflation and the induced gravitational waves provided by the enhanced curvature perturbation after inflation. We show that both of them are potentially testable with the future space-based gravitational wave interferometers.