The top quark chromomagnetic dipole moment in the SM from the 4-body vertex function

Abstract

A new proposal to compute the anomalous chromomagnetic dipole moment of the top quark, μt, in the Standard Model is presented. On the basis of the 5-dimensional effective Lagrangian operator that characterizes the quantum-loop induced chromodipolar vertices gtt and ggtt, the μt anomaly is derived via radiative correction at the 1-loop level from the non-Abelian 4-body vertex function ggtt. We evaluate μt(s) as a function of the energy scale s= E2, for E=[10,1000] GeV, taking into account the running of the quark masses and alpha strong through the MS scheme. In particular, we find that at the typical energy scale E=mZ for high-energy physics, similarly to αs(mZ2), α(mZ2) and sW(mZ2), the spacelike evaluation yields μt(-mZ2) = -0.025+0.00384i and the timelike μt(mZ2) = -0.0318-0.0106i. This Reμt(-mZ2) = -0.025 from ggtt is even closer to the experimental central value μtExp= -0.024, than that coming from the known 3-body vertex function gtt, -0.0224. Once again, the Imμt(-mZ2) part is due to the contribution of virtual charged currents, just like in the gtt case. We can infer that the spacelike prediction is the favored one.

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