摘要
We study J/ψ inclusive production in the decays of P-wave bottomonium χbJ(1P,2P) for J=0,1,2. Within the framework of the non-relativistic QCD(NRQCD) factorization method we calculate the contri-butions coming from four relevant processes including one color-singlet process and three color-octet ones,which are b(3PJ,1) → c(3S1,8) + c +,b(3S1,8) → c(3S1,1) + g + g,b(3S1,8) → c(3S1,1) + c + and b(3S1,8) → c(3S1,8) +g. Our calculation shows that the color-octet processes,especially the gluon fragmen-tation one,contribute the most in the decays of χb0 and χb1. However,the J/ψ production in the χb2 decay is dominated by the color-singlet process. Furthermore,the gluon fragmentation process gives a δ function in the energy fraction distribution of J/ψ,which can be considered to be another characteristic for its identification. From our estimation the branching ratio for these processes is about 10-4-10-5,which indicates that J/ψ inclusive production is detectable at B-factories. Studying these processes would help us to gain a deeper understanding of the color-octet mechanism.
We study J/ψ inclusive production in the decays of P-wave bottomonium χbJ(1P,2P) for J=0,1,2. Within the framework of the non-relativistic QCD(NRQCD) factorization method we calculate the contri-butions coming from four relevant processes including one color-singlet process and three color-octet ones,which are b(3PJ,1) → c(3S1,8) + c +,b(3S1,8) → c(3S1,1) + g + g,b(3S1,8) → c(3S1,1) + c + and b(3S1,8) → c(3S1,8) +g. Our calculation shows that the color-octet processes,especially the gluon fragmen-tation one,contribute the most in the decays of χb0 and χb1. However,the J/ψ production in the χb2 decay is dominated by the color-singlet process. Furthermore,the gluon fragmentation process gives a δ function in the energy fraction distribution of J/ψ,which can be considered to be another characteristic for its identification. From our estimation the branching ratio for these processes is about 10-4-10-5,which indicates that J/ψ inclusive production is detectable at B-factories. Studying these processes would help us to gain a deeper understanding of the color-octet mechanism.
