Probing the in-medium PT-broadening by γ+HF angular de-correlations

Abstract

Angular correlations between vector boson and heavy flavors~(HF) are potentially new effective tools to gain insight into the partonic interactions in the quark-gluon plasma (QGP). In this paper, we present the theoretical study of the azimuthal angular de-correlations of γ+HF in nucleus-nucleus collisions as a new probe of the in-medium PT-broadening effect. The initial production of γ+HF in p+p is generated by SHERPA which matches the next-to-leading hard processes with parton shower. The in-medium heavy quark evolution is implemented by a Monte Carlo Langevin simulation, which takes into account the collisional and radiative energy loss. We observe considerable suppression at φγ Dπ and enhancement at φγ D<2.8 in γ+D azimuthal angular distribution in 0-10\% Pb+Pb collisions at sNN=5.02 TeV compared to the p+p baseline, which indicates evident in-medium PT-broadening of charm quarks. We also find that the overall modification patterns of γ+D angular distribution are sensitive to the selection cut of D meson pT. Furthermore, by constructing the 2D (xJγ D, φγ D) correlation diagram, it's possible to display the respective impacts of the two aspects of jet quenching, energy loss and PT-broadening, on the final-state γ+D observable simultaneously. Additionally, we find weaker angular de-correlations of γ+B compared to γ+D which may be helpful to understand the mass hierarchy in heavy-ion collisions. Finally, the nuclear modification of φγ D distributions in central 0-10\% Au+Au collisions at RHIC energy is provided for completeness.