Jet-Induced Enhancement of Deuteron Production in $pp$ and $p$-Pb Collisions at the LHC

TL;DR

This study investigates how jet-related processes enhance deuteron production in proton-proton and proton-lead collisions at the LHC, revealing significant in-jet coalescence effects that depend on transverse momentum and jet direction.

Contribution

It introduces a detailed analysis of jet-associated deuteron production using the coalescence model and AMPT simulations, highlighting the role of nucleon coalescence within jets at high energies.

Findings

In-jet coalescence factor $B_2^{\text{In-jet}}$ exceeds medium coalescence by factors of 10-25.

Large low-momentum enhancements originate from nucleon coalescence inside jets.

Deuteron production inside jets dominates at higher $p_T$ with increased $d/p$ ratios.

Abstract

Jet-associated deuteron production in $pp$ collisions at $\sqrt{s}=13$ TeV and $p$-Pb collisions at $\sqrt{s_{NN}}=5.02$ TeV is studied in the coalescence model by using the phase-space information of proton and neutron pairs from a multiphase transport (AMPT) model at the kinetic freezeout. In the low transverse momentum ($p_T$) region $p_T/A < 1.5$ GeV/$c$, where $A$ is the mass number of a nucleus, the in-jet coalescence factor $B_2^\text{In-jet}$ for deuteron production, given by the ratio of the in-jet deuteron number to the square of the in-jet proton number, is found to be larger than the coalescence factor $B_2$ in the medium perpendicular to the jet by a factor of about 10 in $pp$ collisions and of 25 in $p-$Pb collisions, which are consistent with the ALICE measurements at the LHC. Such large low-momentum enhancements mainly come from coalescence of nucleons inside the jet with the medium nucleons. Coalescence of nucleons inside the jet dominates deuteron production only at the higher $p_T$ region of $p_T/A\gtrsim 4$ GeV/$c$, where both the yield ratio $d/p$ of deuteron to proton numbers and the $B_2$ are also significantly larger in the jet direction than in the direction perpendicular to the jet due to the strong collinear correlation among particles produced from jet fragmentation. Studying jet-associated deuteron production in relativistic nuclear collisions thus opens up a new window to probe the phase-space structure of nucleons inside jets.