Constraints on Vector-Like Top Dipole Interactions from Top-Associated Photon Measurements at the LHC

Abstract

Vector-like top partners with electric charge +2/3 are predicted in many extensions of the Standard Model and are actively searched for at the LHC through their electroweak decays T Wb, Zt, and Ht. More general scenarios, however, allow dipole interactions that induce radiative decays T tγ and T tg. We reinterpret precision measurements of top-associated photon production to constrain such dipole operators. This approach provides a complementary probe to traditional resonance searches, which rely on direct reconstruction of heavy states, by instead exploiting distortions in precision observables. Using unfolded differential cross sections for ttγ production measured by CMS and the fiducial ttγγ cross section reported by ATLAS, we derive constraints on the electromagnetic and chromomagnetic dipole couplings of a vector like T quark within an effective field theory framework. We present limits in terms of the effective couplings ctγ and ctg, as well as the corresponding branching fractions BR(T tγ) and BR(T tg), for masses in the range 500~GeV mT 2.0~TeV. For mT = 500~GeV, the analysis reaches sensitivity to the electromagnetic dipole coupling as small as ctγ 0.005~TeV-1 in the gluon dominated scenario Bγ = 0.1, while the sensitivity degrades to O(1)~TeV-1 at mT = 2.0~TeV. We find that the ttγ and ttγγ measurements provide complementary sensitivity, probing different regions of parameter space and lifting degeneracies between electromagnetic and chromomagnetic dipole interactions. These results demonstrate that precision measurements of top-associated photon final states provide a powerful and complementary probe of vector-like quarks in scenarios where radiative decays dominate.