Abstract
Using the Coulomb Modified Glauber (CMG) model for interactivity of \(^{84}{\text {Kr}}_{36}\) with NED (Nuclear Emulsion Detector) nuclei at 1 A GeV, we have examined the total nuclear reaction cross-section (CS) for target participants [\(P_\textrm{targ}\)], projectile participants [\(P_\textrm{proj}\)], and binary collisions [\(B_\textrm{C}\)] in this paper. We noted that there is a good compatibility between the average reaction CS with nuclear medium influence and the experimental findings. These estimated CS for nuclear reactions, [\(P_\textrm{proj}\)], [\(P_\textrm{targ}\)] and [\(B_\textrm{C}\)], are tally with the various target groups of the nuclear emulsion nuclei. We have also focused on the azimuthal correlation of gray particles and black particles, shower particles and their dependence on the projectile mass (\(A_\textrm{p}\)) at relativistic energy. The parameters which we have studied are the asymmetry coefficients (\(<\alpha>\) and A). We have observed that the correlation increases linearly with \(A_\textrm{p}\).
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Acknowledgements
The authors wish to express their gratitude to Babita Kumari of GLA University for her insightful remarks and ideas, as well as to the entire technical crew at GSI in Germany for exposing the NED to the \(^{84}\text{ Kr}_{{36}}\) beam at 1 A GeV.
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Rawat, U., Singh, M.K. & Goyal, M. Study the Emission Feature of the Projectile and Target Fragments Using Coulomb Modified Glauber Model and Azimuthal Correlation. Iran J Sci (2024). https://doi.org/10.1007/s40995-024-01615-x
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DOI: https://doi.org/10.1007/s40995-024-01615-x