1 / 20

Daniela Henzlova GSI-Darmstadt, Germany on leave from NPI Rez, Czech Republic

Systematic Investigation of the Isotopic Distributions Measured in the Fragmentation of 124 Xe and 136 Xe Projectiles. Daniela Henzlova GSI-Darmstadt, Germany on leave from NPI Rez, Czech Republic. Motivation.

bryga
Download Presentation

Daniela Henzlova GSI-Darmstadt, Germany on leave from NPI Rez, Czech Republic

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Systematic Investigation of the Isotopic Distributions Measured in the Fragmentation of 124Xe and 136Xe Projectiles Daniela Henzlova GSI-Darmstadt, Germany on leave from NPI Rez, Czech Republic

  2. Motivation • experiments 124Xe(N/Z=1.30)+Pb and 136Xe(N/Z=1.52)+Pb at 1 A GeV performed at FRS allow to identify final residues over broad range of nuclear charge and to study the sensitivity of their isotopic composition to the N/Z of the projectile • extensive data base for comparison with up-to-date parameterizations and/or codes • to test/improve their predictions for RIB facilities • unique experimental information to investigate the properties of highly excited nuclear system • relevant for many astrophysical scenarios: supernovae explosions (formation of elements), properties of neutron stars…

  3. Main aims • extraction of isotopic cross sections in the broad range of Z and comparison with EPAX parameterization and ABRABLA code predictions • investigation of influence of cluster emission during evaporation and of thermal conditions after nuclear break-up on the isotopic composition of the final residues – deviation from the residue corridor • evaporation -> shifts the final isotopic distributions towards residue corridor R.J.Charity, Phys. Rev. C 58 (1998), 1073 • investigation of the isoscaling phenomenon in the broad Z range in the relativistic energy regime and extraction of the symmetry energy coefficient

  4. The experimental set-up

  5. Fragment Separator (FRS) – a high-resolution magnetic spectrometer inverse kinematics in-flight identification mass identification: position in scintillators dE in ionisation chamber ToF Z/ΔZ ~ 200 A/ΔA ~ 400 • high resolving power:

  6. mass resolution with FRS 136Xe + Pb 1A GeV 124Xe + Pb 1A GeV 136Xe 124Xe

  7. Experimental results I – cross sections, comparison with EPAX

  8. Measured cross sections • 136Xe+Pb 1 A GeV • 124Xe+Pb 1 A GeV

  9. Comparison with EPAX – isotopic distributions I • EPAX = empirical parameterization of the fragmentation cross sections • 136Xe+Pb 1 A GeV EPAX for 136Xe+Pb • 124Xe+Pb 1 A GeV EPAX for 124Xe+Pb • underestimation of production cross sections of lighter isotopes • slight underestimation of cross sections of isotopes on the less n-rich side of the isotopic distributions in case of 136Xe projectile

  10. Comparison with EPAX – mean N-over-Z 136Xe • 136Xe+Pb 1 A GeV • 124Xe+Pb 1 A GeV EPAX for 136Xe+Pb EPAX for 124Xe+Pb 124Xe • slightly higher <N>/Z in the vicinity of the 136Xe projectile • scarcer data available for 136Xe projectile when EPAX was formulated • low values of <N>/Z of the residues far from both projectiles • too fast removal of the memory on the initial isotopic composition • present data may be used to refine the EPAX parameterization

  11. Experimental results II – mean N-over-Z, thermal conditions at break-up

  12. <N>/Z in full nuclear charge range 136Xe • 136Xe+Pb 1 A GeV • 124Xe+Pb 1 A GeV 124Xe • <N>/Z investigated in the broad nuclear charge range • cold residues preserve memory on the initial N/Z over the whole nuclear charge range (high excitation energies) residue corridor not reached

  13. Comparison with ABRABLA – abrasion+evaporation and influence of the cluster emission • n, p, alpha emission -> too strong removal of memory on initial N/Z • implementation of cluster emission (IMF) memory on initial N/Z not completely removed not sufficient to reproduce <N>/Z of experimental data

  14. Break-up and backtracking of E* from evaporation 136Xe experimental data abrasion ‹N›/Z~N/Zproj break-up ‹N›/Z~N/Zproj evaporation • knowing final <N>/Z and N/Z of the projectilethe length of the evaporation process may be traced back from E*=aTf2 temperature determines the length of the evaporation cascade

  15. Comparison with ABRABLA – influence of the thermal conditions at the freeze-out of the break-up • <N>/Z of residues from 124Xe less sensitive to length of evaporation cascade • less n-rich projectile final isotopic distribution closer to residue corridor • only including the nuclear break-up allows to reproduce <N>/Z of the final residues Tf=5-8 MeV and 4 MeV for 136Xe and 124Xe, respectively • final <N>/Z reflects the thermal conditions at the freeze-out

  16. Experimental results III - isoscaling and coefficient of symmetry energy

  17. Isoscaling from 136Xe and 124Xe data • overall the isoscaling very well respected over the broad nuclear charge range • a slight deviation from strictly exponential trend in the vicinity of projectile Z due to increasingly nongaussian shape of the isotopic distributions

  18. Exponent of isoscaling from 136Xe and 124Xe data • initial decrease consistent with production of large fragments by evaporation process at small excitation energy • extraction of symmetry energy coefficient residues produced in the multifragment event isoscaling exponent in charge range Z=10-13: α = 0.36±0.01

  19. Extraction of symmetry coefficient • by A. Botvina et al. the following relation between the exponent α and the symmetry energy coefficient γ was derived: Isotopic composition of projectiles Experimental isoscaling temperature of disintegrating system • temperature assumed T ~ 4-6 MeV • in the relativistic energy regime change of Z/A in the abrasion negligible ~ projectile γapp=14±3 MeV • symmetry energy coefficient of residues Z=10-13: • investigation of influence of evaporation with SMM code suggests γreal even lower than γapp • symmetry energy coefficient lower than for cold heavy nuclei, where typically γ~21-25 MeV

  20. Conclusions • isotopic distributions in the broad Z range were obtained for residues from 136Xe (N/Z=1.52) and 124Xe (N/Z=1.30) projectiles • comparison with EPAX suggests slight underestimation of less n-rich isotopes in the vicinity of 136Xe projectile and too strong removal of memory on the initial N/Z present data may serve to refine the EPAX formulation • comparison with ABRABLA suggests that only upon introducing nuclear break-up final <N>/Z may be reproduced final <N>/Z reveal sensitivity to the length of an evaporation cascade following the nuclear break-up additional refinement of the code needed before the realistic quantitative result may be deduced Tf ~ 5-8 MeV for 136Xe Tf ~ 4 MeV for 124Xe • isoscaling phenomenon observed in the broad Z range from residues with Z=10-13the symmetry energy coefficient γapp=14±3 MeV was extracted comparison with SMM calculations supports decrease of symmetry coefficient for hot fragments

More Related