Transport of angular momentum in damped nuclear reactions

Randrup, J.

doi:10.1016/0375-9474(82)90087-2

Cited by 150 publications

(51 citation statements)

References 41 publications

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“…However, difficulties exist in modeling these reactions due to their timedependent non-equilibrium nature. The portioning of excitation energy between the final fragments [3,[24][25][26], the amount of irreversible energy dissipation as opposed to excitation of collective modes, conversion of angular momentum to intrinsic spins of the final fragments [27], influence of transfer [23,28,29] have all been subject to experimental [15,[30][31][32] scrutiny with often less than satisfactory comparisons [3,33]. Part of the complication arises from the model dependence of the experimental analysis.…”

Section: Introductionmentioning

confidence: 99%

Transport properties of isospin asymmetric nuclear matter using the time-dependent Hartree-Fock method

Umar

Simenel

2017

Phys. Rev. C

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Background: The study of deep-inelastic reactions of nuclei provide a vehicle to investigate nuclear transport phenomena for a full range of equilibration dynamics. These inquires provide us the ingredients to model such phenomena and help answer important questions about the nuclear Equation of State (EOS) and its evolution as a function of neutron-to-proton (N/Z) ratio.Purpose: The motivation is to examine the real-time dynamics of nuclear transport phenomena and its dependence on (N/Z) asymmetry from a microscopic point of view to avoid any pre-conceived assumptions about the involved processes.Method: Time-dependent Hartree-Fock (TDHF) method in full 3D is employed to calculate deep-inelastic reactions of 78 Kr+ 208 Pb and 92 Kr+ 208 Pb systems at 8.5 MeV/A. The impact parameter and energy-loss dependence of relevant observables are calculated. In addition, density constrained TDHF method is used to compute excitation energies of the primary fragments. The statistical deexcitation code GEMINI is utilized to examine the final reaction products.Results: The kinetic energy loss and sticking times as a function of impact parameter are calculated. Final properties of the fragments (charge, mass, scattering angle, kinetic energy) are computed. Their evolution as a function of energy loss is studied and various intra-relations are investigated. The fragment excitation energy sharing is computed. Conclusions:We find a smooth dependence of the energy loss, E loss , on the impact parameter for both systems. On the other hand the transfer properties for low E loss values are very different for the two systems but become similar in the higher E loss regime. The mean life time of the charge equilibration process, obtained from the final (N − Z)/A value of the fragments, is shown to be ∼ 0.5 zs. This value is slightly larger (but of the same order) than the value obtained from reactions at Fermi energies.

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Section: Introductionmentioning

confidence: 99%

Transport properties of isospin asymmetric nuclear matter using the time-dependent Hartree-Fock method

Umar

Simenel

2017

Phys. Rev. C

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“…An isoscaling study was carried out on the reactions 86 Kr+ 112 Sn and 86 Kr+ 124 Sn at 25 AMeV [3] and a correlation of the isoscaling parameter with isospin equilibration was observed [7]. Peripheral nucleus-nucleus collisions can be described theoretically using the model of deep-inelastic transfer [8] in combination with an appropriate model of de-excitation. Very good description of experimental observables was obtained [2,5,6,9] using the DIT model of Tassan-Got [10] and the de-excitation codes SMM [11] and GEMINI [12].…”

Section: Introductionmentioning

confidence: 99%

Effect of nuclear periphery on nucleon transfer in peripheral collisions

Veselský

Souliotis

2006

Nuclear Physics A

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A comparison of experimental heavy residue cross sections from the reactions 86 Kr+ 64 Ni, 112,124 Sn with the model of deep-inelastic transfer ( DIT ) is carried out. A modified expression for nucleon transfer probabilities is used at non-overlapping projectile-target configurations, introducing a dependence on isospin asymmetry at the nuclear periphery. The experimental yields of neutron-rich nuclei close to the projectile are reproduced better and the trend deviating from the bulk isospin equilibration is explained. For the neutron-rich products further from the projectile, originating from hot quasiprojectiles, the statistical multifragmentation model reproduces the mass distributions better than the model of sequential binary decay. In the reaction with proton-rich target 112 Sn the nucleon exchange appears to depend on 1 isospin asymmetry of nuclear periphery only when the surface separation is larger than 0.8 fm due to the stronger Coulomb interaction at more compact di-nuclear configuration.

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“…According to the Langevin equation, neglecting contributions from the drift term, the variance is related to the diffusion coefficient according to [31,32] …”

Section: Variance Of Fragment Mass Distribution In Transfer Reactionsmentioning

confidence: 99%

Beyond mean-ﬁeld approach to heavy-ion reactions around the Coulomb barrier

Washiyama

Lacroix

Ayık

et al. 2011

EPJ Web of Conferences

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Abstract. Dissipation and fluctuations of one-body observables in heavy-ion reactions around the Coulomb barrier are investigated with a microscopic stochastic mean-field approach. By projecting the stochastic meanfield dynamics on a suitable collective path, transport coefficients associated with the relative distance between colliding nuclei and a fragment mass are extracted. Although microscopic mean-field approach is know to underestimate the variance of fragment mass distribution, the description of the variance is much improved by the stochastic mean-field method. While fluctuations are consistent with the empirical (semiclassical) analysis of the experimental data, concerning mean values of macroscopic variables the semiclassical description breaks down below the Coulomb barrier.

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Transport of angular momentum in damped nuclear reactions

Cited by 150 publications

References 41 publications

Transport properties of isospin asymmetric nuclear matter using the time-dependent Hartree-Fock method

Transport properties of isospin asymmetric nuclear matter using the time-dependent Hartree-Fock method

Effect of nuclear periphery on nucleon transfer in peripheral collisions

Beyond mean-ﬁeld approach to heavy-ion reactions around the Coulomb barrier

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