Impact of nuclear deformation on particle production in Ne+Ne collisions at sqrt(sNN)=5.36 TeV from AMPT-SM

Abstract

We present a systematic study of particle production in Ne+Ne collisions at sNN = 5.36 TeV using the A Multi-Phase Transport (AMPT) model with string melting (SM) configuration. The analysis compares spherical and deformed configurations of 20Ne to investigate the influence of initial-state nuclear deformation on bulk observables. Charged-particle pseudorapidity ( dNch/dη ) densities, identified particle yields (dN/dy), transverse momentum (pT) spectra, mean transverse momentum ( pT ), and pT-differential particle ratios (K/π and p/π) are studied as functions of multiplicity and centrality. The results show that all observables exhibit the expected dependence on event activity, including smooth multiplicity scaling, mass ordering in pT , and characteristic features associated with radial flow and quark coalescence. Differences between the two configurations on bulk observables remain small across all observables, typically at the level of a 2\%--6\% percent, with slightly enhanced sensitivity observed in peripheral collisions. These findings suggest that, within the AMPT-SM framework, the collective dynamics and hadrochemical composition are primarily governed by the overall system density and interaction dynamics, while the influence of initial-state deformation is subleading. This study provides a baseline for understanding deformation effects in light-ion collision systems and highlights the limited sensitivity of bulk observables to initial nuclear geometry in transport-based approaches.