English

Kaon-deuteron correlation function from an effective field theory approach

Nuclear Theory 2026-07-07 v1 High Energy Physics - Phenomenology

Abstract

We present a study of femtoscopic correlation functions for KdK^{-}d and K+dK^{+}d pairs, and compare our results with recent measurements by the ALICE Collaboration in both Pb-Pb and high-multiplicity pppp collisions. The kaon-deuteron wave functions are derived from scattering amplitudes using a unitarized chiral effective theory model describing the elementary interactions of K±K^{\pm} mesons with nucleons. We then evaluate the K±dK^{\pm}d strong scattering amplitudes by solving the Faddeev equations within two distinct frameworks: the Impulse Approximation and the Fixed Center Approximation, which accounts for multiple scatterings. We also incorporate the long-range Coulomb effects between the kaon and the deuteron. We show that the KdK^{-}d correlation function exhibits large sensitivity to both the size of the emitting source and the relative momentum of the pair, being heavily influenced by rescattering processes. In contrast, the K+dK^{+}d correlation function is dominated by the weakly repulsive K+NK^{+}N interaction, showing deviations from purely Coulombic behavior only at small emission source sizes. Our predictions are in agreement with the ALICE experimental data, and also with the energy-shift and width of the 1s1s level of the kaonic deuterium preliminary results from the SIDDHARTA 2 Collaboration.

Cite

@article{arxiv.2607.06715,
  title  = {Kaon-deuteron correlation function from an effective field theory approach},
  author = {Juan Torres-Rincon and Àngels Ramos},
  journal= {arXiv preprint arXiv:2607.06715},
  year   = {2026}
}

Comments

8 pages, 2 figures. Presented by Juan Torres-Rincon at the Excited QCD 2026 Workshop in Granada (Spain), on January 10, 2026. To be published in Acta Physica Polonica B