Particle Production via Strings and Baryon Stopping within a Hadronic Transport Approach

TL;DR

This paper develops a string-based hadronic transport model to quantitatively describe baryon stopping in heavy ion collisions at SPS and RHIC energies, matching experimental proton and pion rapidity spectra and providing insights into string fragmentation.

Contribution

The work introduces a tuned string model within a hadronic transport approach that accurately reproduces baryon stopping and rapidity spectra in heavy ion collisions, aiding future initial condition modeling.

Findings

Successfully reproduces proton rapidity spectra shape change with energy

Achieves good agreement with measured proton and pion spectra

Provides insights into string fragmentation and formation times

Abstract

The stopping of baryons in heavy ion collisions at beam momenta of $p_{\rm lab} = 20-160A$ GeV is lacking a quantitative description within theoretical calculations. Heavy ion reactions at these energies are experimentally explored at the Super Proton Synchrotron (SPS) and the Relativistic Heavy Ion Collider (RHIC) and will be studied at future facilities such as FAIR and NICA. Since the net baryon density is determined by the amount of stopping, this is the pre-requisiste for any investigation of other observables related to structures in the QCD phase diagram such as a first-order phase transition or a critical endpoint. In this work we employ a string model for treating hadron-hadron interactions within a hadronic transport approach (SMASH, Simulating Many Accelerated Strongly-interacting Hadrons). Free parameters of the string excitation and decay are tuned to match experimental measurements in elementary proton-proton collisions, where some mismatch in the $x_F$ distribution of protons is still present. Afterwards, the model is applied to heavy ion collisions, where the experimentally observed change of the shape of the proton rapidity spectrum from a single peak structure to a double peak structure with increasing beam energy is reproduced. Heavy ion collisions provide the opportunity to study the formation process of string fragments in terms of formation times and reduced interaction cross-sections for pre-formed hadrons. A good agreement with the measured rapidity spectra of protons and pions is achieved while insights on the fragmentation process are obtained. In the future, the presented approach can be used to create event-by-event initial conditions for hybrid calculations.