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NLO fragmentation functions for a quark into a spin-singlet quarkonium: Same flavor case

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 Added by Xu-Chang Zheng
 Publication date 2021
  fields
and research's language is English




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In the paper, we calculate the fragmentation functions for $c to eta_c$ and $b to eta_b$ up to next-to-leading-order (NLO) QCD accuracy. The ultraviolet divergences in the real corrections are removed through operator renormalization under the modified minimal subtraction scheme. We then obtain the fragmentation functions $D_{c to eta_c}(z,mu_F)$ and $D_{b to eta_b}(z,mu_F)$ up to NLO QCD accuracy, which are presented as figures and fitting functions. The numerical results show that the NLO corrections are significant. The sensitives of the fragmentation functions to the renormalization scale and the factorization scale are analyzed explicitly.



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In the paper, we calculate the fragmentation functions for a quark to fragment into a spin-singlet quarkonium, where the flavor of the initial quark is different from that of the constituent quark in the quarkonium. The ultraviolet divergences in the phase space integral are removed through the operator renormalization under the modified minimal subtraction scheme. The fragmentation function $D_{q to eta_Q}(z,mu_F)$ is expressed as a two-dimensional integral. Numerical results for the fragmentation functions of a light quark or a bottom quark to fragment into the $eta_c$ are presented. As an application of those fragmentation functions, we study the processes $Z to eta_c+qbar{q}g(q=u,d,s)$ and $Z to eta_c+bbar{b}g$ under the fragmentation and the direct nonrelativistic QCD approaches.
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