Abstract
The decay of the compound nucleus is traditionally calculated using one of two types of statistical models, either a sequential or a simultaneous emission one. The best known sequential emission models are the Weisskopf-Ewing one and the Hauser-Feshbach one. Both sequential emission models emit only one particle at a time. A well know simultaneous emission model is the Fermi breakup one, which takes into account the fragmentation of the compound nuclei into two, three or more residual nuclei/particles. We have compared the particle and residual nucleus distributions of the Weisskopf-Ewing and Fermi breakup models in the case in which only stable nuclei/particles are emitted. We find that the Weisskopf-Ewing results in larger yields of light particles and heavy residues than the Fermi breakup model, while the latter results in larger yields of intermediate mass fragments.
NUCLEAR REACTIONS
Comparison between models of the decay of light compound nuclei
V. G. Rezende; B. V. Carlson
Instituto Tecnológico da Aeronáutica, Departamento de Física, Praça Marechal Eduardo Gomes, 50, 12228-900, São José dos Campos, SP, Brazil
ABSTRACT
The decay of the compound nucleus is traditionally calculated using one of two types of statistical models, either a sequential or a simultaneous emission one. The best known sequential emission models are the Weisskopf-Ewing one and the Hauser-Feshbach one. Both sequential emission models emit only one particle at a time. A well know simultaneous emission model is the Fermi breakup one, which takes into account the fragmentation of the compound nuclei into two, three or more residual nuclei/particles. We have compared the particle and residual nucleus distributions of the Weisskopf-Ewing and Fermi breakup models in the case in which only stable nuclei/particles are emitted. We find that the Weisskopf-Ewing results in larger yields of light particles and heavy residues than the Fermi breakup model, while the latter results in larger yields of intermediate mass fragments.
I. INTRODUCTION
The decay of the compound nuclei is traditionally calculated using statistical models of sequential emission [1]. The most commonly used models of this type are the Weisskopf-Ewing [2] one (which does not take angular moment conservation into account) and the Hauser-Feshbach [3] one (which does). In both models, the decay of the compound nucleus to a residual nucleus occurs through sequential particle emission, until not enough energy remains for further emission.
In light compound nuclei, the excitation energy for complete disintegration of the system is relatively low and is easily reached in reactions. A model that can take this disintegration into account is the Fermi breakup one [4]. In both the sequential emission and breakup models, the cross section is written as the product of a formation cross and a branching ratio for decay, a form characteristic of decay from a statistically equilibrated system. In this project, we compare the distribution of particles and residual nuclei that results from calculations of the Weisskopf-Ewing model of sequential emission and the Fermi breakup one.
II. WEISSKOPF-EWING MODEL
The Weisskopf-Ewing cross section can be written as
The emission factor Yc is proportional to the absorption cross section and can be written as
where µc is the reduced mass in channel c and ec is the center-of-mass energy of the channel.
The emission factor Yc must be modified to take into account the density of states. This factor for the Weisskopf-Ewing model is given by the expression
Yc(ec) ® Yc(ec)wc(Ec)dec,
where wc() is the level density of the residual nucleus, with
and Bc is the separation energy of the particle emitted in channel c.
The Weisskopf-Ewing cross section can thus be written as
In the calculations using the model, we use a global fit to the absorption cross sections, Gilbert-Cameron level densities and a level density parameter of a = A/7.1 (MeV)1. We consider the emission of particle-bound nuclei of mass A < 7. Ground states masses are taken from the 1998 mass table of Audi-Wapstra.
III. FERMI BREAKUP MODEL
Here, the total kinetic energy E for a breakup into n fragments is calculated using the expression
where mb and eb are the masses and excitation energies of the fragments and ECoul is the Coulomb barrier for the channel, given by
where V/V0 = 1 is normally used.
The Fermi breakup cross section takes the form
where wc is the emission rate from channel c.
The total probability for separation in n components in channel b is given by the expression
where V is the decay volume of the system and W = (2p)3 is the normalization volume of the system.
The density of final states rb(E) can be defined as the product of three factors,
rb(E) = Mn(E)SnGn,
where the first term is the phase space factor, defined as,
where is the momentum of fragment bj.
The second term is the spin factor determined by the expression
which furnishes the number of states with different spin orientations.
The last term is the permutation factor given by
which takes into account the identity of the fragments in the final state, where is the number of particles of type bj. In the calculations shown, we include all particle-bound states of the decay products and also consider the nucleus 8Be, due to its long lifetime. Ground states masses are taken from the 1998 mass table of Audi-Wapstra.
IV. CONCLUSIONS
Overall, as shown in Figs. 1 and 2, we find that the Weisskopf-Ewing calculations result in the production of more light particles and heavy residues, while the Fermi breakup calculations yield more intermediate mass residues. This is probably due to the fact that the emisson of particle-unbound nuclei has not been considered in the Fermi breakup calculations. Such emissions are observed experimentally. We plan to include them in the future.
Received on 11 August, 2005
- [1] E. Fermi, Prog. Theor. Phys. 5, 570 (1950).
- [2] B. V. Carlson, A Brief Overview of Models of Nucleon- Induced Reactions, ICTP Lecture Notes 12, 181 (2002).
- [3] W. Hauser and H. Fesbach, Phys. Rev. 87, 366 (1952).
- [4] A. S. Botvina, A. S. Iljinov, I. N. Mishustin, J. P. Bondorf, R. Donangelo, and Sneppen, Nucl. Phys. A 475, 663 (1987).
Publication Dates
-
Publication in this collection
07 Nov 2005 -
Date of issue
Sept 2005
History
-
Received
11 Aug 2005