The next-to-leading-order QCD correction to inclusive J/() production in Z0 decay

Abstract

In this paper, we study the J/() production in Z boson decay in color-singlet model(CSM). We calculate the next-to-leading-order (NLO) QCD correction to Z Quarkonium+QQ, the dominant contribution in the CSM, with the vector and axial-vector parts in ZQQ vertex being treated separately. The results show that the vector and axial-vector parts have the same K factor (the ratio of NLO result to leading-order result) 1.13 with the renormalization scale μ=2mc and mc=1.5GeV, and the K factor falls to 0.918 when applying the Brodsky, Lepage, and Mackenzie(BLM) renormalization scale scheme with obtained μBLM=2.28GeV and mc=1.5GeV. By including the contributions from the next-dominant ones, the photon and gluon fragmentation processes, the branching ratio for Z J/prompt+X is (7.3 10.0)× 10-5 with the uncertainty consideration for the renormalization scale and Charm quark mass. The results are about half of the central value of the experimental measurement 2.1×10-4. Furthermore, the J/ energy distribution in our calculation is not well consistent with the experimental data. Therefore, even at QCD NLO, the contribution to Z J/prompt+X from the CSM can not fully account for the experimental measurement. And there should be contributions from other mechanisms, such as the color-octet(COM) contributions. We define Rcc=(Z J/ ccX)(Z J/ X) and obtain Rcc=0.84 for only CSM contribution and Rcc=0.49 for COM and CSM contributions together. Then Rcc measurement could be used to clarify the COM contributions.