Double Monodromy Inflation: A Gravity Waves Factory for CMB-S4, LiteBIRD and LISA

TL;DR

This paper proposes a double monodromy inflation model that predicts detectable gravitational wave signals across CMB, LiteBIRD, and LISA, with unique chiral and enhanced features due to vector fluctuations.

Contribution

It introduces a novel two-stage monodromy inflation scenario with matter domination, predicting multiple observable gravitational wave signatures for upcoming experiments.

Findings

Predicts relic gravity waves with r between 0.02 and 0.06.

Shows vector fluctuations lead to chiral, enhanced gravitational waves.

Provides a unified model testable by CMB-S4, LiteBIRD, and LISA.

Abstract

We consider a short rollercoaster cosmology based on two stages of monodromy inflation separated by a stage of matter domination, generated after the early inflaton falls out of slow roll. If the first stage is controlled by a flat potential, $V \sim \phi^p$ with $p < 1$ and lasts ${\cal N} \sim 30 - 40$ efolds, the scalar and tensor perturbations at the largest scales will fit the CMB perfectly, and produce relic gravity waves with $0.02 \lesssim r \lesssim 0.06$, which can be tested by LiteBIRD and CMB-S4 experiments. If in addition the first inflaton is strongly coupled to a hidden sector $U(1)$, there will be an enhanced production of vector fluctuations near the end of the first stage of inflation. These modes convert rapidly to tensors during the short epoch of matter domination, and then get pushed to superhorizon scales by the second stage of inflation, lasting another $20-30$ efolds. This band of gravity waves is chiral, arrives today with wavelengths in the range of $10^8$ km, and with amplitudes greatly enhanced compared to the long wavelength CMB modes by vector sources. It is therefore accessible to LISA. Thus our model presents a rare early universe theory predicting several simultaneous signals testable by a broad range of gravity wave searches in the very near future.