English

The phase transition in hot $\Lambda$ hypernuclei within relativistic Thomas-Fermi approximation

Nuclear Theory 2016-11-30 v1

Abstract

A self-consistent description for hot Λ\Lambda hypernuclei in hypothetical big boxes is developed within the relativistic Thomas-Fermi approximation in order to investigate directly the liquid-gas phase coexistence in strangeness finite nuclear systems. We use the relativistic mean-field model for nuclear interactions. The temperature dependence of Λ\Lambda hyperon density, Λ\Lambda hyperon radius, excitation energies, specific heat, and the binding energies of Λ\Lambda hypernuclei from Λ16^{16}_{\Lambda}O to Λ208^{208}_{\Lambda}Pb in phase transition region are calculated by using the subtraction procedure in order to separate the hypernucleus from the surrounding baryon gas. The Λ\Lambda central density is very sensitive to the temperature. The radii of Λ\Lambda hyperon at high temperature become very large. In the relativistic Thomas-Fermi approximation with the subtraction procedure, the properties of hypernuclei are independent of the size of the box in which the calculation is performed. The level density parameters of hypernuclei in the present work are confirmed to be almost constant at low temperature. It is also found that the single-Λ\Lambda binding energies of Λ\Lambda hypernuclei are largely reduced with increasing temperature.

Keywords

Cite

@article{arxiv.1611.04121,
  title  = {The phase transition in hot $\Lambda$ hypernuclei within relativistic Thomas-Fermi approximation},
  author = {Jinniu Hu and Zhaowen Zhang and Shishao Bao and Hong Shen},
  journal= {arXiv preprint arXiv:1611.04121},
  year   = {2016}
}

Comments

20 pages, 8 figures, 2 tables, accepted to Phys. Rev. C. arXiv admin note: text overlap with arXiv:1411.1584

R2 v1 2026-06-22T16:50:39.438Z