Bottom hadro-chemistry in high-energy hadronic collisions

Abstract

The hadro-chemistry of bottom quarks (b) produced in hadronic collisions encodes valuable information on the mechanism of color-neutralization in these reactions. Since the b-quark mass is much larger than the typical hadronic scale of 1\,GeV, b b pair production is expected to be well separated from subsequent hadronization processes. A significantly larger fraction of b baryons has been observed in proton-proton (pp) and proton-antiproton (pp) reactions relative to e+e- collisions, challenging theoretical descriptions. We address this problem by employing a statistical hadronization approach with an augmented set of b-hadron states beyond currently measured ones, guided by the relativistic quark model and lattice-QCD computations. Assuming relative chemical equilibrium between different b-hadron yields, thermal densities are used as fragmentation weights of b-quarks into various hadron species. With quark model estimates of the decay patterns of excited states, the fragmentation fractions of weakly-decaying b hadrons are computed and found to agree with measurements in pp collisions at the Tevatron. By combining transverse-momentum (pT) distributions of b-quarks from perturbative QCD with thermal weights and independent fragmentation toward high pT, a fair description of the pT-dependent Bs0/B- and b0/B- ratios measured in pp collisions at the LHC is obtained. Finally, we implement the hadro-chemistry into a strongly-coupled transport approach for b-quarks in heavy-ion collisions, utilizing previously determined b-quark transport coefficients in the Quark-Gluon Plasma, to highlight the modifications of hadro-chemistry and collective behavior of b hadrons in Pb-Pb collisions at the LHC.