Hubble-Scale Tachyonic Shocks from Low-Scale Inflation -- A New Gravitational-Wave Window on Inflation

TL;DR

This paper proposes that low-scale inflation can produce observable gravitational waves through a tachyonic instability leading to shock waves, offering a new window for detecting inflationary physics with current and future gravitational-wave detectors.

Contribution

It introduces a novel mechanism where tachyonic instabilities at the end of low-scale inflation generate gravitational waves, expanding the potential for observational probes of inflationary models.

Findings

Gravitational waves from tachyonic shocks can be detected by pulsar timing arrays and ground-based detectors.

Current gravitational-wave limits already constrain certain low-scale inflation models.

Inflation at MeV--EeV scales can produce observable signals in existing and upcoming experiments.

Abstract

Current bounds on the tensor-to-scalar ratio imply that the energy scale of inflation may lie below the grand-unified scale. In this paper, we show that in a broad class of single-field inflation models with sufficiently small energy scales, an extremely efficient tachyonic instability develops at the end of inflation. This instability rapidly drives the system into a nonlinear regime before coherent oscillations can be established, leading to a first-order phase-transition--like phenomenon without tunneling or barrier crossing. The resulting ultra-relativistic shock fronts surrounding the bubble interiors expand to near the Hubble scale, corresponding to the most strongly enhanced tachyonic modes, and collide with one another, producing energetic inflaton particles and gravitational waves. As a result, the post-inflationary dynamics can differ significantly from the conventional high-scale inflationary scenario. Interestingly, inflation at MeV--EeV energy scales can be probed via gravitational-wave observations, including pulsar timing arrays, ground-based detectors, and future space-based experiments. Recent limits from the LIGO--KAGRA--Virgo collaboration already constrain EeV-scale inflation, while pulsar timing array results may be interpreted as evidence for gravitational waves generated by GeV-scale inflation. We also briefly discuss further implications of the resulting tachyonic shocks.