Heavy Flavor Azimuthal Correlations in Cold Nuclear Matter

TL;DR

This study uses next-to-leading order calculations to analyze how transverse momentum broadening affects azimuthal correlations of heavy flavor quark pairs in small collision systems, providing insights relevant for interpreting heavy-ion collision data.

Contribution

It introduces NLO calculations with $k_T$ broadening for azimuthal correlations in small systems, highlighting their impact on low $p_T$ distributions and agreement with experimental data.

Findings

Low $p_T$ azimuthal distributions are highly sensitive to $k_T$ broadening.

NLO contributions can cause enhancement at $ heta o 0$, matching experimental data.

$k_T$ broadening significantly modifies azimuthal correlations in small collision systems.

Abstract

Background: It has been proposed that the azimuthal distributions of heavy flavor quark-antiquark pairs may be modified in the medium of a heavy-ion collision. Purpose: This work tests this proposition through next-to-leading order (NLO) calculations of the azimuthal distribution, $d\sigma/d\phi$, including transverse momentum broadening, employing $<k_T^2>$ and fragmentation in exclusive $Q \bar Q$ pair production. While these studies were done for $p+p$, $p + \bar p$ and $p+$Pb collisions, understanding azimuthal angle correlations between heavy quarks in these smaller, colder systems is important for their interpretation in heavy-ion collisions. Methods: First, single inclusive $p_T$ distributions calculated with the exclusive HVQMNR code are compared to those calculated in the fixed-order next-to-leading logarithm approach. Next the azimuthal distributions are calculated and sensitivities to $<k_T^2>$, $p_T$ cut, and rapidity are studied at $\sqrt{s} = 7$ TeV. Finally, calculations are compared to $Q \bar Q$ data in elementary $p+p$ and $p + \bar p$ collisions at $\sqrt{s} = 7$ TeV and 1.96 TeV as well as to the nuclear modification factor $R_{p {\rm Pb}}(p_T)$ in $p+$Pb collisions at $\sqrt{s_{NN}} = 5.02$ TeV measured by ALICE. Results: The low $p_T$ ($p_T < 10$ GeV) azimuthal distributions are very sensitive to the $k_T$ broadening and rather insensitive to the fragmentation function. The NLO contributions can result in an enhancement at $\phi \sim 0$ absent any other effects. Agreement with the data was found to be good. Conclusions: The NLO calculations, assuming collinear factorization and introducing $k_T$ broadening, result in significant modifications of the azimuthal distribution at low $p_T$ which must be taken into account in calculations of these distributions in heavy-ion collisions.