English

Semiclassical shell-structure micro-macroscopic approach for the level density

Nuclear Theory 2021-10-20 v2

Abstract

Level density ρ(E,A)\rho(E,A) is derived for a one-component nucleon system with a given energy EE and particle number AA within the mean-field semiclassical periodic-orbit theory beyond the saddle-point method of the Fermi gas model. We obtain   ρIν(S)/Sν~~\rho \propto I_\nu(S)/S^\nu, with Iν(S)I_\nu(S) being the modified Bessel function of the entropy SS. Within the micro-macro-canonical approximation (MMA), for a small thermal excitation energy, UU, with respect to rotational excitations, ErotE_{\rm rot}, one obtains ν=3/2\nu=3/2 for ρ(E,A)\rho(E,A). In the case of excitation energy UU larger than ErotE_{\rm rot} but smaller than the neutron separation energy, one finds a larger value of ν=5/2\nu=5/2. A role of the fixed spin variables for rotating nuclei is discussed. The MMA level density ρ\rho reaches the well-known grand-canonical ensemble limit (Fermi gas asymptotic) for large SS related to large excitation energies, and also reaches the finite micro-canonical limit for small combinatorial entropy SS at low excitation energies (the constant "temperature" model). Fitting the ρ(E,A)\rho(E,A) of the MMA to the experimental data for low excitation energies, taking into account shell and, qualitatively, pairing effects, one obtains for the inverse level density parameter KK a value which differs essentially from that parameter derived from data on neutron resonances.

Keywords

Cite

@article{arxiv.2103.16480,
  title  = {Semiclassical shell-structure micro-macroscopic approach for the level density},
  author = {A. G. Magner and A. I. Sanzhur and S. N. Fedotkin and A. I. Levon and S. Shlomo},
  journal= {arXiv preprint arXiv:2103.16480},
  year   = {2021}
}

Comments

21 pages, 4 figures, 1 Table

R2 v1 2026-06-24T00:42:00.113Z