Investigating J/ψ spin alignment in heavy-ion collisions within a two-component transport model

Abstract

We investigate the spin alignment of J/ψ mesons in relativistic heavy-ion collisions within a two-component Boltzmann transport model. Starting from the relativistic spin Boltzmann equation, we derive the spin density matrix element ρ00 under a non-relativistic approximation for heavy quarks. To interpret the recent ALICE measurements in Pb+Pb collisions, the observed ρ00 is described as a pT-dependent mixture of contributions from primordial production and the coalescence process. At forward rapidity, the pT dependence of charmonium ρ00 is well reproduced by this two-component mechanism: at low pT, charmonium production is dominated by the coalescence of partially polarized charm quarks induced by thermal vorticity; with increasing pT, primordially produced charmonia become dominant, causing ρ00 to approach 1/3. To further test this spin alignment mechanism, we provide predictions for the J/ψ ρ00 in the mid-rapidity region, which exhibits a distinct pT trend due to the kinematic suppression of the thermal vorticity contribution. This study elucidates the underlying mechanism of J/ψ spin alignment and advances our understanding of heavy quarkonium spin dynamics in strongly interacting matter.

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