Energy loss baseline for light hadrons in oxygen-oxygen collisions at sNN=5.36\,TeV

Abstract

I present predictions for inclusive charged hadron spectra in minimum-bias proton-proton and oxygen-oxygen collisions at a centre-of-mass energy of sNN = 5.36\,TeV, assuming no final-state interactions. Using next-to-leading order perturbative QCD matrix elements, along with state-of-the-art (nuclear) parton distribution and fragmentation functions, I establish a baseline for the nuclear modification factor RhAA in oxygen-oxygen collisions in the absence of quenching. Theoretical uncertainties in this baseline are found to be substantial for transverse momenta below 20\,GeV. In the intermediate range 20\,GeV pTh 70\,GeV, these uncertainties are significantly reduced to approximately 5\%. At higher momenta (pTh 70\,GeV), however, predictions exhibit a marked spread due to differences between fragmentation functions, reflecting varying assumptions about isospin symmetry. Finally, I show that considering neon-neon collisions in the initial state or neutral pions in the final state does not appreciably change the nuclear modification factor.