16 September 2015, 11:00, LIT room 310

Seminars, 03 September 2015

1. Galoyan A.S., Uzhinsky V.V. "Monte Carlo Event Generators for NICA/MPD and CBM Experiments"

Abstract
An improved version of Glauber Monte Carlo simulation code is proposed which allows to estimate geometrical properties of nucleus-nucleus interactions in the energy range ECMS from 5 GeV upto 20 TeV. Using the code it is shown that the properties of interactions at the energies 5 — 10 GeV (NICA/MPD and
CBM) are quite close to that at energy 200 GeV (RHIC). The properties can be extracted from experimental observabilities using various techniques. The most promising one is a registration of spectator neutrons from nuclear residuals. As shown in the paper, events generators predict various neutron multiplicities. Thus, a registration of the neutrons will allow to make a step in understanding of decay of high excited nuclei.


2. MikhailovaT.I.1, Erdemchimeg B.1,2, Lukyanov S. M.1, Artukh A.G.1, Sereda Yu. M.1, Di Toro M.3, Wolter H. H.4 (1Joint Institute for Nuclear Research, Dubna, Russia; 2Nuclear Research Center, Mongolian National University, Ulanbaator, Mongolia ; 3Lab. Naz. del Sud, INFN, Catania, Italy; 4Fac. of Physics,University of Munich, Garching, Germany) "PROJECTILE FRAGMENTATION OF 40,48Ca IN A TRANSPORT APPROACH"

Abstract
The fragmentation at low energies is of interest in the production of exotic nuclei, but the detailed mechanism is not completely understood.  Here  we  cal-culate  isotope  and  velocity  distributions  for reactions of 48Ca and 40Ca with heavy (181Ta) and light (9Be) targets at 140 AMeV incident energy, for which  also  data  exist  in  the  literature.  The  characteristics  of  primary  fragments  are  calculated  in  a transport  approach,  namely  the  Boltzmann-Nordheim-Vlasov  (BNV)  approach.  We  evaluate  the excitation  energies  of  the  primary  fragments  in  a  consistent  way  with  the  same  interaction  as  in  the transport  cal-culations.  To  take  into  account  the  de-excitation  of  the  primary  fragments  we  use  the Statistical Multifragmentation Model (SMM) of Bondorf, et al.The secondary decay is necessary to be able to compare to the experimental data. Isotope distributions are described reasonably well, but velocity distributions are generally too narrow. Comparing the two projectiles we can obtain information on the nuclear symmetry energy. The yield ratio of 40Ca and 48Ca determines the isoscaling parameters, which are proportional to the symmetry energy in the decaying system.