Probing the mass effect of heavy quark jets in high-energy nuclear collisions
Abstract
The production of heavy quark (HQ) jets provides a new arena to address the mass effect of jet quenching in heavy-ion physics. This paper presents a theoretical study of HQ jet yield suppression in Pb+Pb collisions at the LHC and focuses on the energy loss of HQ jets produced by different mechanisms. The p+p baseline is carried out by the SHERPA generator, and the jet-medium interactions are described by the SHELL transport model, which considers the elastic and inelastic partonic energy loss in the quark-gluon plasma (QGP). In p+p collisions, our numerical results indicate that the HQ jets from gluon splitting (g → Q-jet) give the dominant contribution at high pT, and it shows more dispersive structures than the HQ-initiated one (Q → Q-jet). In nucleus-nucleus collisions, our calculations are consistent with the inclusive and b-jet RAA recently measured by the ATLAS collaboration, which suggests a remarkable manifestation of the mass effect of jet energy loss. As a result of the dispersive substructure, the g → Q-jet will lose more energy than the Q → Q-jet in the QGP. Due to the significant contribution of g → c-jet, the RAA of c-jet will be comparable or even smaller than that of inclusive jet. To experimentally distinguish the g → Q-jet and Q → Q-jet, we propose the event selection strategies based on their topological features and test the performances. By isolating the c → c-jet and b → b-jet, the jets initiated by heavy quarks, we predict that the order of their RAA are in line with the mass hierarchy of energy loss. Future measurements on the RAA of Q → Q-jet and g → Q-jet will provide a unique chance to test the flavor/mass dependence of energy loss at the jet level.
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