Multiplicity and entropy scaling of medium-energy protons emitted in relativistic heavy-ion collisions

• Published in: Journal of the Korean Physical Society Vol. 67; no. 7; pp. 1150 - 1157
• Main Authors: Abdelsalam, A., Kamel, S., Hafiz, M. E.
• Format: Journal Article
• Language: English
• Published: Seoul The Korean Physical Society 01.10.2015; 한국물리학회
• Subjects: Mathematical and Computational Physics; Particle and Nuclear Physics; Physics; Physics and Astronomy; Theoretical; 물리학; Nucleus-nucleus collisions; Multiplicity distributions; Multiplicity moments; Target fragments; KNO-scaling
• ISSN: 0374-4884; 1976-8524
• DOI: 10.3938/jkps.67.1150

The behavior and the properties of medium-energy protons with kinetic energies in the range 26 - 400 MeV is derived from measurements of the particle yields and spectra in the final state of relativistic heavy-ion collisions ( 16 O-AgBr interactions at 60 A and 200 A GeV and 32 S-AgBr interactions at 3.7 A and 200 A GeV) and their interpretation in terms of the higher order moments. The multiplicity distributions have been fitted well with the Gaussian distribution function. The data are also compared with the predictions of the modified FRITIOF model, showing that the FRITIOF model does not reproduce the trend and the magnitude of the data. Measurements of the ratio of the variance to the mean show that the production of target fragments at high energies cannot be considered as a statistically independent process. However, the deviation of each multiplicity distribution from a Poisson law provides evidence for correlations. The KNO scaling behavior of two types of scaling (Koba-Nielsen-Olesen (KNO) scaling and Hegyi scaling) functions in terms of the multiplicity distribution is investigated. A simplified universal function has been used in each scaling to display the experimental data. An examination of the relationship between the entropy, the average multiplicity, and the KNO function is performed. Entropy production and subsequent scaling in nucleus-nucleus collisions are carried out by analyzing the experimental data over a wide energy range (Dubna and SPS). Interestingly, the data points corresponding to various energies overlap and fall on a single curve, indicating the presence of a kind of entropy scaling.