Production of single-charm hadrons by quark combination mechanism in p-Pb collisions at sNN=5.02 TeV

Abstract

If QGP-like medium is created in p-Pb collisions at extremely high collision energies, charm quarks that move in the medium can hadronize by capturing the co-moving light quark(s) or anti-quark(s) to form the charm hadrons. Using light quark pT spectra extracted from the experimental data of light-flavor hadrons and a charm quark pT spectrum that is consistent with perturbative QCD calculations, the central-rapidity data of pT spectra and the spectrum ratios for D mesons in the low pT range (pT7 GeV/c) in minimum-bias p-Pb collisions at sNN=5.02 TeV are well described by quark combination mechanism in equal-velocity combination approximation. The c+/D0 ratio in quark combination mechanism exhibits the typical increase-peak-decrease behavior as the function of pT, and the shape of the ratio for pT3 GeV/c is in agreement with the data of ALICE collaboration in central rapidity region -0.96<y<0.04 and the preliminary data of LHCb collaboration in forward rapidity region 1.5<y<4.0. The global production of single-charm baryons is quantified using the data and the possible enhancement (relative to light flavor baryons) is discussed. The pT spectra of c0, c0 in minimum-bias events and those of single-charm hadrons in high-multiplicity event classes are predicted, which serves as the further test of the possible change of the hadronization characteristic for low pT charm quarks in the small system created in p-Pb collisions at LHC energies.