English

Spin/Parity Dependent Level Density

Nuclear Theory 2021-04-07 v1 Nuclear Experiment

Abstract

It is shown that the Constant Temperature (CT) model of nuclear level density is a direct consequence of a symmetrized Poisson distribution of nuclear level spacings. The standard CT model describing the total level density is shown to be fatally flawed due to discontinuities at the Yrast energies, the onset of new JπJ^{\pi} sequences, that disrupt the exponential formula and cause the back shift parameter to become nonphysically negative. A new CT-JPI level density model is proposed with a constant temperature and separate back shift parameters for each JπJ^{\pi} sequence. The CT-JPI model is also constrained to reproduce the spin distribution predicted by Ericson's spin distribution function at the neutron separation energy. A fitting procedure is described for determining the temperature TT, back shifts E0(Jπ)E_0(J^{\pi}), and spin cutoff parameters σc\sigma_c from nuclear structure and resonance data. The CT-JPI model is demonstrated to successfully predict the level densities for a wide range of spins and parities for 46 nuclear with Z=7-92. In variance with earlier predictions the spin cut-off parameters show no mass dependence and instead substantial variation at all mass regions.

Keywords

Cite

@article{arxiv.2104.02693,
  title  = {Spin/Parity Dependent Level Density},
  author = {Richard B. Firestone},
  journal= {arXiv preprint arXiv:2104.02693},
  year   = {2021}
}
R2 v1 2026-06-24T00:53:56.861Z