Multiplicities of forward$ndash$backward particles in 32S$ndash$emulsion interactions at 4.5 A GeV/c

Kamel²,

Hafiz³

et al. 2014

Section: Experimental Techniquementioning

confidence: 99%

Results on the scaling of multiplicity distributions of fast target fragments in high energy nucleus-nucleus collisions

Kamel²,

Hafiz³

et al. 2014

“…Consequently, the produced compound nucleus will de-excite and decay by emitting this excess number of backward hadrons. Such a mechanism of compound target nucleus was discussed in experiments (29,30) . Therefore, regarding the nuclear limiting fragmentation beyond 1A GeV, the projectile energy cannot be considered an effective parameter in the backward production and consequently does not mean that, this system of particle production is a creation system.…”

Section: Multiplicity Distributionsmentioning

confidence: 99%

Interactions in nuclear emulsion detector irradiated by a-particle

Abou-Moussa²,

Osman³

et al. 2014

Using the multiplicity characteristics of the final state hadron, the shower particles emitted in the 4-pspace through 4He interactions with emulsion nuclei are studied in a few A GeV region. Basing on a universality of state, the multiplicity distributions, in the backward hemisphere of the space, are determined as a function of the target size. The shower particle multiplicity, while found to depend only on the target size in the backward hemisphere, depends on both the energy and system size in the forward hemisphere. It is seen that the shower particles are originated from two emission sources. One of both emits pion in the backward hemisphere, beyond the kinematic limits, as a target source particle regarding the limiting fragmentation hypothesis. The other is the main source which emits pion in the forward hemisphere as a result of a particle creation system. The results are analyzed in the framework of the Lund Monte-Carlo program code-events generating FRITIOF model.

“…The dependence of the average values of shower, gray, and black particles on interaction centrality degrees is also studied in this work. This degree could be sufficiently indicated by the value of N h [28][29][30][31] such that as the interaction becomes more central, the value of N h increases. Consequently, the present interactions are classified into five main groups with N h ranging from 0-1, 2-7, 8-15, 16-27 or 28.…”

Section: Dependence On the Impact Parametermentioning

confidence: 99%

“…Next, we check the effect of both the interaction centrality degree and the projectile mass number, A Proj , on the forward-backward ratios for shower and gray [24,28,[32][33][34][35]] that the backward shower particle production is a consequence of a decay of the most high excited target system after the emission of the forward particles and hence, such production depends mainly on the target size. The results shown in Table 4 agree with the previous conclusion where the (F/B) s ratios decrease with the increase of N h , i.e.…”

Section: Forward-backward Ratiosmentioning

confidence: 99%

Multiplicity characteristics in relativistic²⁴Mg-nucleus collisions

Shaat²,

Abou-Moussa³

et al. 2013

Chinese Phys. C

This work is concerned with the analyses of the shower and gray particle production in 4.5 A GeV/c 24 Mg collision with emulsion nuclei. The highest particle production occurs in the region of the low impact parameters. While the multiplicity of the shower particles emitted in the forward direction depends on the projectile mass number and energy, the multiplicity of the backward ones shows a limiting behaviour. The source of the emission of the forward shower particles is completely different from that of the backward ones. The target fragments are produced in a thermalized system of emission.