The effect of hadronic scatterings on the measurement of vector meson spin alignments in heavy-ion collisions

TL;DR

This study investigates how hadronic scatterings influence the measurement of vector meson spin alignments in heavy-ion collisions, revealing that such interactions can distort observed signals, especially for certain mesons and kinematic conditions.

Contribution

The paper introduces a detailed analysis of hadronic effects on vector meson spin alignment measurements using a multi-phase transport model, clarifying discrepancies in experimental observations.

Findings

Hadronic scatterings cause deviations in observed $ ho_{00}$ for $ ho$ and $K^*$ mesons.

The effect on $ ho_{00}$ depends on pseudorapidity coverage, being more significant with limited $ m eta$.

The effect is negligible for the $ m phi$ meson.

Abstract

Spin alignments of vector mesons and hyperons in relativistic heavy-ion collisions have been proposed as signals of the global polarization. The STAR experiment first observed the $\rm \Lambda$ polarization. Recently, the ALICE collaboration measured the transverse momentum ($p_T$) and the collision centrality dependence of $K^*$ and $\phi$ spin alignments in Pb-Pb collisions at $\rm \sqrt{s_{NN}}$ = 2.76 TeV. A large signal is observed in the low $p_T$ region of mid-central collisions for $K^*$ while the signal is much smaller for $\phi$, and these have not been understood yet. Since vector mesons have different lifetimes and their decay products have different scattering cross sections, they suffer from different hadronic effects. In this paper, we study the effect of hadronic interactions on the spin alignment of $K^*$, $\phi$ and $\rho$ mesons in relativistic heavy-ion collisions with a multi-phase transport model. We find that hadronic scatterings lead to a deviation of the observed spin alignment matrix element $\rho_{00}$ away from the true value for $\rho$ and $K^*$ mesons (with a bigger effect on $\rho$) while the effect is negligible for the $\phi$ meson. The effect depends on the kinematic acceptance: the observed $\rho_{00}$ value is lower than the true value when the pseudorapidity ($\eta$) coverage is small while there is little effect when the $\eta$ coverage is big. Our study thus provides valuable information to understand the vector meson spin alignment signals observed in the experiments.