Expectation of forward-backward rapidity correlations in $p+p$ collisions at the LHC energies

TL;DR

This study compares experimental forward-backward rapidity correlations in $p+ar{p}$ collisions with PYTHIA and PHOJET models, revealing energy-dependent behaviors and potential saturation effects relevant for understanding particle production mechanisms at LHC energies.

Contribution

It provides the first detailed comparison of experimental and model predictions of forward-backward correlations across a wide energy range, highlighting differences and saturation phenomena.

Findings

Correlation strength decreases with rapidity gap.

Experimental correlation shows linear dependence on ln(sqrt{s}).

Model predictions deviate from experimental trends, indicating different underlying physics.

Abstract

Forward-backward correlation strength ($b$) as a function of pesudorapidity intervals for experimental data from $p+\bar{p}$ non-singly diffractive collisions are compared to PYTHIA and PHOJET model calculations. The correlations are discussed as a function of rapidity window ($\Delta \eta$) symmetric about the central rapidity as well as rapidity window separated by a gap ($\eta_{gap}$) between forward and backward regions. While the correlations are observed to be independent of $\Delta \eta$, it is found to decrease with increase in $\eta_{gap}$. This reflects the role of short range correlations and justifies the use of $\eta_{gap}$ to obtain the accurate information about the physics of interest, the long range correlations. The experimental $b$ value shows a linear dependence on $\ln \sqrt{s}$ with the maximum value of unity being reached at $\sqrt{s}$ = 16 TeV, beyond the top LHC energy. However calculations from the PYTHIA and PHOJET models indicate a deviation from linear dependence on $\ln \sqrt{s}$ and saturation in the $b$ values being reached beyond $\sqrt{s}$ = 1.8 TeV. Such a saturation in correlation values could have interesting physical interpretations related to clan structures in particle production. Strong forward-backward correlations are associated with cluster production in the collisions. The average number of charged particles to which the clusters fragments, called the cluster size, are found to also increase linearly with $\ln \sqrt{s}$ for both data and the models studied. The rate of increase in cluster size vs. $\ln \sqrt{s}$ from models studied are larger compared to those from the data and higher for PHOJET compared to PYTHIA. Our study indicates that the forward-backward measurements will provide a clear distinguishing observable for the models studied at LHC energies.