Heavy quarkonium electric dipole transitions in non-relativistic quantum field theory

Abstract

In this work we use the low-energy EFT called potential non-relativistic QCD (pNRQCD) to calculate the partial decay width of different bb-states undergoing an electric dipole transition at next-to-next-to leading order (NNLO). Explicitly, the b J, for J=0,1,2, and the hb are investigated by computing the processes b J + γ and hb ηb + γ. Relativistic corrections of relative order v2 to the leading electric dipole operator are included. The analysis separates those contributions that account for the electromagnetic interaction terms in the pNRQCD Lagrangian, which are v2 suppressed, and those that account for quarkonium state corrections of relative order v and v2. Within the last ones, corrections come from higher order potentials (1m and 1m2 terms), and from higher order Fock states which account for the coupling of the quark-antiquark state to other low-energy degrees of freedom and thus demand non-perturbative input. Finally, the experimentally known branching fractions are used to predict the total decay with of the respective initial states.