Vector-Like top quark production via a chromo-magnetic moment at the LHC

TL;DR

This paper investigates novel production mechanisms for vector-like top and bottom quark partners at the LHC, focusing on chromomagnetic interactions to extend the search reach up to about 3 TeV, surpassing traditional methods.

Contribution

It introduces new search channels based on chromomagnetic interactions for vector-like quark partners, expanding the mass reach and complementing existing LHC search strategies.

Findings

Current chromomagnetic interaction searches constrain bottom-quark partners.

Top-partner production via bottom-partner decay is viable in certain parameter regions.

Masses up to 3 TeV can be probed with these new channels.

Abstract

Theories which provide a dynamical explanation for the large top-quark mass often include TeV-scale vector-like top-quark and bottom-quark partner states which can be potentially discovered at the LHC. These states are currently probed through model-independent searches for pair-production via gluon fusion, as well as through model-dependent complementary electroweak single production. In this paper we study the potential to extend those searches for the partners of the third-generation Standard Model quarks on the basis of their expected chromomagnetic interactions. We discuss how current searches for "excited" bottom-quarks produced via $b$-gluon fusion through chromomagnetic interactions are relevant, and provide significant constraints. We then explore the region of the parameter space in which the bottom-quark partner is heavier than the top-quark partner, in which case the top-partner can be primarily produced via the decay of the bottom-partner. Next, we probe the potential of the production of a single top-quark partner in association with an ordinary top-quark by gluon-fusion. Kinematically these two new processes are similar, and they yield the production of a heavy top partner and a lighter Standard Model state, a pattern which allows for the rejection of the associated dominant Standard Model backgrounds. We examine the sensitivity of these modes in the case where the top-partner subsequently decays to a Higgs boson and an ordinary top-quark, and we demonstrate that these new channels have the potential of extending and complementing the conventional strategies at LHC run III and at the high-luminosity phase of the LHC. In this last case, we find that partner masses that range up to about 3 TeV can be reached. This substantially expands the expected mass reach for these new states, including regions of parameter space that are inaccessible by traditional searches.