Kaon-deuteron correlation function from an effective field theory approach
Abstract
We present a study of femtoscopic correlation functions for and pairs, and compare our results with recent measurements by the ALICE Collaboration in both Pb-Pb and high-multiplicity collisions. The kaon-deuteron wave functions are derived from scattering amplitudes using a unitarized chiral effective theory model describing the elementary interactions of mesons with nucleons. We then evaluate the 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 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 correlation function is dominated by the weakly repulsive 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 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