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Cyclotron Institute, Texas A&M University

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1 Cyclotron Institute, Texas A&M University
Use of a Nucleation Based Ternary Fission Model to Reproduce Neck Emission in Heavy-Ion Reactions Jerome Gauthier Cyclotron Institute, Texas A&M University SOTANCP4 May 2018

2 Ternary fission: about 0
Ternary fission: about 0.3% of heavy nucleus fissions produce a third fragment coming from the low density neck region. 241Pu Fission Fragment Ternary Fission

3 S. Wuenschel et al., Physical Review C 90, 011601 (2014)
Most of those fragments are α particles. A high yield of tritons relative to protons is observed and the heavy fragment yields are decreasing with Z. The use of a nuclear statistical equilibrium (NSE) model based on the chemical potential for low density and temperature is in pretty good agreement with experimental observations for A≤15. To reproduce the heavier fragment yields, one has to take into account the reaction time and the critical cluster size (nucleation). S. Wuenschel et al., Physical Review C 90, (2014)

4 This behavior should not be restricted to fission necks and is more likely to be a general nuclear matter property. It thus needs to be studied at higher temperature. Mid-peripheral collisions with a heavy system like 124Sn+124Sn are similar to the fission process but at higher temperature and density. We want to see if NSE with nucleation (NESC) calculation can reproduce the mid-rapidity (ternary fission like) isotopic yields. We use 124Sn+124Sn and 124Sn+112Sn at 26A MeV from the December 2007 NIMROD experiment.

5 Nimrod Detection Array
Neutron Ball 156 CsI(Tl) distributed on 11 rings from 3 to 100o. 100 Si (300µm)-CsI(Tl) telescopes from ring 2 to 9. 30 Si(150µm)-Si(500µ)-CsI(Tl) super telescopes from ring 2 to 9. 4π neutron detector array (Neutron Ball).

6 Peripheral and mid-peripheral event selection:
Zmax > 20 Multiplicity > 1

7 Relative angle selection
The relative angle between the biggest fragment (Zmax) and the fragment of interest velocity vectors is calculated in order to select the mid-rapidity emission. Laboratory frame CM frame

8 Relative Angle Window Selection
Vcm Vproj Charge versus parallel velocity for several relative angle windows centered at 90o in the center of mass.

9 Relative Angle Window Selection
To select the ternary-like-fragments the relative angle (in the center of mass) should be close to 90o. But the statistic goes down very quickly when shrinking that window. To maximize the statistic, we select the interval for which <Ecm> stops to drop. The o selection seems to be a good compromise.

10 Isotopic Yield Evaluation
Each isotope count of a particular Z is multiplied by a correction factor to take into account: missing detectors imperfect isotopic identification energy thresholds

11 NSEC Fitting (colored lines)
Fit free parameter values for Z<15 minimization: T = 2.76 MeV Time = 6000 fm/c ρ = 18.67x10-4 fm-3 Z/A=0.47 Ac = 15.8 M2 (for Z<15)=1.11 NSEC Fitting (colored lines) Be Li C B N O Na F Mg Ne Al Si T = 2.72 MeV Time = 7300 fm/c ρ = 16.38x10-4 fm-3 Z/A=0.44 Ac = 16.1 M2 (for Z<15)=1.07 Li Be B C O N Ne Mg F Na Al Si

12 NSEC Fitting (Z only) Fit free parameter values for Z only minimization: T = 2.33 MeV Time = fm/c ρ = 14.2x10-4 fm-3 Z/A=0.42 Ac = 16.0 M2 =0.29 T = 2.35 MeV Time = fm/c ρ = 14.2x10-4 fm-3 Z/A=0.42 Ac = 16.0 M2 =0.28

13 NSEC Fit Parameters System 124Sn+112Sn 124Sn+124Sn 241Pu Selection
Isotope A Temperature (MeV) 2.76 2.72 1.4 Density (10-4 fm-3) 18.67 16.38 4 Time (fm/c) 6000 7300 6400 Ac 15.8 16.1 5.4 Proton ratio (system) 0.47 (0.42) 0.44 (0.40) 0.34 (0.39) Fit Metric 1.11 1.07 1.18 0.561 Using Albergo light particle yield ratio temperature measurement*: *S. Albergo et al., Il Nuovo Cimento, vol. 89 A, N. 1 (1985).

14 Equilibrium constant Work still in progress
We calculate several K using the Sn+Sn system (KSn) and 241Pu fission (KPu). We know KSn, KPu, TSn, TPu, and assuming ground states for Pu (first approximation) we know ΔGoPu, so we can extract ΔGoSn. ΔGoSn is 33% higher than ΔGoPu (in average). Work still in progress

15 Collaborators to this work
Summary We are able to apply the NSEC model to heavy-ion collisions with reasonable results. Most of the fit parameters are in a realistic range. Equilibrium constant ratio calculation results are promising. Collaborators to this work J. Gauthier, M. Barbui, X. Cao, K. Hagel, R. Wada, S. Wuenschel and J. B. Natowitz. Special thanks to Alan McIntosh and Sherry Yennello for useful discussions and advices.

16 Thank you for being listening!

17 C. Eccles et al., Physical Review C 96, 054611 (2017).

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