Non-Decoupling New Particles
Abstract
We initiate the study of a new class of beyond the Standard Model states that we call "Loryons." They have the defining characteristic of being non-decoupling, in the sense that their physical mass is dominated by a contribution from the vacuum expectation value of the Higgs boson. The stakes are high: the discovery of a Loryon would tell us that electroweak symmetry must be non-linearly realized in the effective field theory of the Standard Model. Loryons have their masses bounded from above by perturbative unitarity considerations and thus define a finite parameter space for exploration. After providing a complete catalog of Loryon representations under mild assumptions, we turn to examining the constraints on the parameter space from Higgs couplings measurements, precision electroweak tests, and direct collider searches. We show that most fermionic candidates are already ruled out (with some notable exceptions), while much of the scalar Loryon parameter space is still wide open for discovery.
Cite
@article{arxiv.2110.02967,
title = {Non-Decoupling New Particles},
author = {Ian Banta and Timothy Cohen and Nathaniel Craig and Xiaochuan Lu and Dave Sutherland},
journal= {arXiv preprint arXiv:2110.02967},
year = {2022}
}
Comments
55 pages, 11 figures, 13 tables