First direct access to the 0p interaction via correlation studies at the LHC

Abstract

Direct measurements of the 0p interaction have remained so far elusive, with most insights derived indirectly from photoproduction or low-energy partial wave analyses. This letter presents the first direct observation of the 0p interaction, obtained through two-particle correlations measured in high-multiplicity, ultrarelativistic proton-proton collisions at s = 13 TeV by the ALICE Collaboration at the LHC. Two-particle correlation data, analyzed within chiral effective field theory () using a coupled-channel approach and incorporating recent φ-p data, yield a scattering length of a0p = (-0.46 0.04) + i(0.20 0.04) fm and constrain coupling strengths of two states identified with the N(1958) and N(1700). These findings emphasize the importance of coupled-channel dynamics and dynamically generated states in understanding the 0p interaction. The results establish a vacuum baseline for extrapolation studies to high densities, contributing to the foundation for chiral symmetry restoration searches, and offer collider-based insights into the QCD spectrum, complementing traditional low-energy approaches. This work marks a significant advance in correlation studies, extending the exploration of interactions to the most short-lived QCD states.