Quantitative predictions of alpha-charmonium correlation functions in high-energy collisions

TL;DR

This study models alpha-charmonium interactions using first-principles potentials, revealing weak binding and long-range correlations that vary with spin configurations and source sizes in high-energy collisions.

Contribution

It introduces a first-principles approach to compute alpha-charmonium potentials and analyzes their impact on correlation functions in high-energy collisions.

Findings

Alpha-J/psi system is loosely bound with 0.1-0.6 MeV binding energy.

Different spin interactions significantly affect correlation functions.

Correlation functions vary notably with source size and density model.

Abstract

Two-body $ ^{4}\textrm{He}\left(\alpha\right)$-charmonium $ \left(c\bar{c}\right) $ potentials in the single-folding potential (SFP) approach are built by using a first principles HAL QCD low-energy $ NJ/\psi$ and $ N\eta_{c} $ interactions. The $N\textrm{-}c\bar{c}$ potentials are observed to exhibit an attractive nature across all distances, accompanied by a characteristic long-range tail. It is found that the $ \alpha\textrm{-}J/\psi $ system appears to be loosely bound with the central binding energy in the range of 0.1-0.6 MeV, while for spin-$ 1/2 $ $\alpha\textrm{-}\eta_{c}$, no bound or resonance state (with respect to the $ \alpha \textrm{-} c\bar{c} $ threshold) was found. The $ \alpha\textrm{-}c\bar{c} $ correlation function in high-energy collisions is examined to explore the $ N\textrm{-}c\bar{c} $ interaction. The analysis revealed that variations in spin-dependent $\alpha\textrm{-}c\bar{c}$ interactions-spin-$3/2$ $\alpha\textrm{-}J/\psi$, spin-$1/2$ $\alpha\textrm{-}J/\psi$, spin-$1/2$ $\alpha\textrm{-}\eta_c$, and the spin-averaged $\alpha\textrm{-}J/\psi$-produce noticeable differences in the $\alpha\textrm{-}c\bar{c}$ correlation function, especially when the source size is around $ 3 $ fm. It is found that different results are produced by the Lednicky-Lyuboshits formula at small source sizes. This indicates that a relatively long-range interaction exists for the $ \alpha\textrm{-}c\bar{c} $ system. Furthermore, a comparison has been conducted between two density functions of $ ^{4}\textrm{He}$ the central depression (CD) and the simple single Gaussian (SG) density-both of which share an identical rms radius of 1.56 fm. Although the $\alpha\textrm{-}J/\psi$ binding energies for the two models are nearly indistinguishable, their corresponding correlation functions demonstrate markedly different behaviors.