Effective Lagrangian for Two-photon and Two-gluon Decays of P-wave Heavy Quarkonium c0,2 and b0,2 states

Abstract

In the traditional non-relativistic bound state calculation, the two-photon decay amplitudes of the P-wave c0,2 and b0,2 states depend on the derivative of the wave function at the origin which can only be obtained from potential models. However by neglecting the relative quark momenta, the decay amplitude can be written as the matrix element of a local heavy quark field operator which could be obtained from other processes or computed with QCD sum rules technique or lattice simulation. Following the same line as in recent work for the two-photon decays of the S-wave ηc and ηb quarkonia, we show that the effective Lagrangian for the two-photon decays of the P-wave c0,2 and b0,2 is given by the heavy quark energy-momentum tensor local operator or its trace, the QQ scalar density and that the expression for c0 two-photon and two-gluon decay rate is given by the f_c0 decay constant and is similar to that of ηc which is given by fηc. From the existing QCD sum rules value for f_c0, we get 5 keV for the c0 two-photon width, somewhat larger than measurement, but possibly with large uncertainties.