Abstract
Within the framework of nonrelativistic QCD (NRQCD) factorization, we calculate the next-to-leading-order (NLO) perturbative corrections to the radiative decay Υ → ηc(χcJ) + γ. Both the helicity amplitudes and the helicity decay widths are obtained. It is the first computation for the processes involving both bottomonium and charmonium at two-loop accuracy. By employing the Cheng-Wu theorem, we are able to convert most of complex-valued master integrals (MIs) into real-valued MIs, which makes the numerical integration much efficient. Our results indicate the mathcal{O}left({alpha}_sright) corrections are moderate for ηc and χc2 production, and are quite marginal for χc0 and χc1 production. It is impressive to note the NLO corrections considerably reduce the renormalization scale dependence in both the decay widths and the branching fractions for χcJ, and slightly improve that for ηc. With the NRQCD matrix elements evaluated via the Buchmüller-Tye potential model, we find the decay width for ηc production is one-order-of-magnitude larger than χcJ production, which may provide a good opportunity to search for Υ → ηc + γ in experiment. In addition, the decay width for χc1 production is several times larger than those for χc0,2. Finally, we find the NLO NRQCD prediction for the branching fraction of Υ → χc1 + γ is only half of the lower bound of the experimental data measured recently by Belle. Moreover, there exists serious contradiction between theory and experiment for Υ → ηc + γ. The discrepancies between theory and experiment deserve further research efforts.
Highlights
Within the framework of nonrelativistic QCD (NRQCD) factorization, we calculate the next-to-leading-order (NLO) perturbative corrections to the radiative decay Υ → ηc(χcJ ) + γ. Both the helicity amplitudes and the helicity decay widths are obtained. It is the first computation for the processes involving both bottomonium and charmonium at two-loop accuracy
With the NRQCD matrix elements evaluated via the Buchmüller-Tye potential model, we find the decay width for ηc production is one-order-of-magnitude larger than χcJ production, which may provide a good opportunity to search for Υ → ηc + γ in experiment
We choose two benchmark values of the masses of charm and bottom quarks: mc = 1.483 GeV and mb = 4.580 GeV, which corresponds to the one-loop heavy quark pole masses, and mc = 1.68 GeV and mb = 4.78 GeV, which corresponds to the two-loop heavy quark pole masses
Summary
It is of some advantage to utilize the helicity amplitude formalism to analyze the hard exclusive decay process. SDC of the corresponding helicity amplitude, and the NRQCD long-distance matrix elements (LDMEs). Where we use the relativistic normalization for the heavy quark states in the computation of full QCD amplitude A(λH1,)λ2 and NRQCD matrix elements. The relativistically normalized color-singlet/spin-triplet projector for Υ meson reads. The amplitude of bb(3S1) → cc(3PJ ) + γ can be projected out by differentiating the color-singlet/spin-triplet quark-level amplitude with respect to the relative momentum q, followed by setting q to zero: A(cc(3PJ )) = ∗(J) d Tr[Π1AΠμ] , μν dqν. We have collected all the necessary ingredients to evaluate the quark-level helicity amplitudes A(λH1,)λ2 in perturbative QCD. It is straightforward to ascertain the SDCs following eq (3.6), and further compute the physical helicity amplitudes (3.1) and partial widths (2.1)
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