English

On nuclear coalescence in small interacting systems

High Energy Physics - Phenomenology 2021-06-02 v2 Nuclear Theory

Abstract

The formation of light nuclei can be described as the coalescence of clusters of nucleons into nuclei. In the case of small interacting systems, such as dark matter and e+ee^+e^- annihilations or pppp collisions, the coalescence condition is often imposed only in momentum space and hence the size of the interaction region is neglected. On the other hand, in most coalescence models used for heavy ion collisions, the coalescence probability is controlled mainly by the size of the interaction region, while two-nucleon momentum correlations are either neglected or treated as collective flow. Recent experimental data from pppp collisions at LHC have been interpreted as evidence for such collective behaviour, even in small interacting systems. We argue that these data are naturally explained in the framework of conventional QCD inspired event generators when both two-nucleon momentum correlations and the size of the hadronic emission volume are taken into account. To include both effects, we employ a per-event coalescence model based on the Wigner function representation of the produced nuclei states. This model reproduces well the source size for baryon emission and the coalescence factor B2B_2 measured recently by the ALICE collaboration in pppp collisions.

Keywords

Cite

@article{arxiv.2012.04352,
  title  = {On nuclear coalescence in small interacting systems},
  author = {M. Kachelriess and S. Ostapchenko and J. Tjemsland},
  journal= {arXiv preprint arXiv:2012.04352},
  year   = {2021}
}

Comments

9 pages, 6 pdf figures; v2: minor changes, added references, accepted version

R2 v1 2026-06-23T20:48:40.285Z