Electroweak phase transition in the 2HDM: Collider and gravitational wave complementarity

TL;DR

This paper explores how collider experiments and gravitational wave observations can jointly investigate the Higgs potential in the 2HDM, focusing on phase transition characteristics and potential signals at HL-LHC and LISA.

Contribution

It demonstrates the complementarity of collider and gravitational wave data in probing the 2HDM Higgs potential and identifies key signatures of strong first-order phase transitions.

Findings

HL-LHC can probe a wide parameter space for strong phase transitions.

Scalar decays to heavy fermions are promising signals.

Strong first-order transitions are favored at lower scalar masses.

Abstract

The knowledge of the Higgs potential is crucial for understanding the origin of mass and the thermal history of our Universe. We show how collider measurements and observations of stochastic gravitational wave signals can complement each other to explore the multiform scalar potential in the two Higgs doublet model (2HDM). Accounting for theoretical and current experimental constraints, we analyze the key ingredients in the shape of the Higgs potential triggering the transmutation in phase transition, from the smooth crossover to the strong first-order phase transition ($\xi_c>1$), focusing on the barrier formation and the upliftment of the true vacuum. In particular, we observe that the $\xi_c>1$ regime is favored for lower scalar masses, rendering strong extra motivation for collider searches. We contrast the dominant collider signals at the HL-LHC (high-luminosity LHC) with observable gravitational wave signals at LISA. We obtain that the HL-LHC will be able to cover a vast range of the $\xi_c>1$ parameter space, with scalar decays to heavy fermions $(H,A,H^\pm\to tt, tb)$ being the most promising smoking gun signature of a strong first-order electroweak phase transition in the 2HDM.