High Energy Vector Boson Scattering in Four-Body Final States to Probe Higgs Cubic, Quartic, and HEFT interactions

Abstract

We compute the energy scales of perturbative unitarity violation in various 2 4 vector boson scattering (VBS) processes and compare them to lower multiplicity processes. The final states include h4, VL VL h h, and VL4, where VL represents the longitudinal mode of Z or W boson, and h the Higgs boson. We consider scenarios with modified cubic and quartic Higgs self-couplings, including those derived from the Standard Model Effective Field Theory (SMEFT), as well as scenarios involving derivative operators from Higgs Effective Field Theory (HEFT). Modified Higgs self-couplings typically lead to perturbative unitarity violation in at least the 2 3 VBS; however, the corresponding energy scales of unitarity violation are often very high. Our analysis reveals that, in the case of modified Higgs potentials, 24 processes exhibit significantly lower energy scales of unitarity violation compared to 2 3 processes. This, combined with the fact that the cross sections of 2 4 processes increase with energy, suggests they generate more signal events at high energies, s 2 TeV, which could be achieved in future colliders. In contrast, for HEFT derivative interactions, higher multiplicity offers diminished benefits, as 2 4 cross sections are often smaller than those of related 2 3 processes within the valid energy range. This study shows that 2 4 VBS processes are particularly compelling for probing Higgs potential modification, including the cubic and quartic couplings, but are less advantageous when derivative interactions dominate.