Gravitational Waves as a Probe of Left-Right Symmetry Breaking

TL;DR

This paper explores whether gravitational wave signals from phase transitions in minimal left-right symmetric models can serve as a new probe, potentially revealing new physics beyond collider experiments.

Contribution

It demonstrates that gravitational wave searches can complement collider studies in probing left-right symmetry breaking, identifying parameter regions with observable signals.

Findings

Significant parameter space with first-order phase transitions

Potential for observable gravitational wave signals with moderate fine-tuning

New calculations of thermal masses relevant for future studies

Abstract

Left-right symmetry at high energy scales is a well-motivated extension of the Standard Model. In this paper we consider a typical minimal scenario in which it gets spontaneously broken by scalar triplets. Such a realization has been scrutinized over the past few decades chiefly in the context of collider studies. In this work we take a complementary approach and investigate whether the model can be probed via the search for a stochastic gravitational wave background induced by the phase transition in which $SU(3)_C \times SU(2)_L \times SU(2)_R \times U(1)_{B-L}$ is broken down to the Standard Model gauge symmetry group. A prerequisite for gravitational wave production in this context is a first-order phase transition, the occurrence of which we find in a significant portion of the parameter space. Although the produced gravitational waves are typically too weak for a discovery at any current or future detector, upon investigating correlations between all relevant terms in the scalar potential, we have identified values of parameters leading to observable signals. This indicates that, given a certain moderate fine-tuning, the minimal left-right symmetric model with scalar triplets features another powerful probe which can lead to either novel constraints or remarkable discoveries in the near future. Let us note that some of our results, such as the full set of thermal masses, have to the best of our knowledge not been presented before and might be useful for future studies, in particular in the context of electroweak baryogenesis.