Anisotropic flows of light-flavor and charmed hadrons in Pb+Pb collisions at LHC energy
Abstract
We apply a constituent quark equal-velocity combination (EVC) model to study the elliptic flow (v2) and triangular flow (v3) of light-flavor and single-charmed hadrons in Pb+Pb collisions at sNN= 2.76 and 5.02 TeV. v2,3 of hadrons in the EVC model can be expressed as a linear superposition of the v2,3 of quarks at the same velocity as that of the hadrons. We find that available experimental data for v2 and v3 of p, , , and as the function of transverse momentum (pT) can be consistently explained by the EVC formula using a v2 of up/down quarks and a v2 of strange quarks. In comparison with v2 data of φ at sNN=2.76 TeV which can be naturally explained by v2 of strange quarks, explanation of data of φ mesons at sNN=5.02 TeV requires an additional contribution of two-kaon coalescence, which indicates approximately 20% influence of final-state hadronic rescattering on v2 of φ at sNN=5.02 TeV. Using v2 and v3 of light-flavor quarks obtained in studying light-flavor hadrons and v2 and v3 of charm quarks determined from D0 meson data, we apply the EVC model to predict the anisotropic flows of Ds+, c+, c0, and c0 and compare them with the available experimental data. The preliminary data for v2 of D0, Ds+, and c+ at sNN= 5.36 TeV are found to be naturally described by the EVC model.
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