Effects of the symmetry energy on the isovector properties of neutron-rich nuclei within a Thomas-Fermi approach

Papazoglou, M. C.; Moustakidis, Ch. C.

doi:10.1103/physrevc.90.014305

Cited by 5 publications

(8 citation statements)

References 90 publications

(89 reference statements)

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“…8, along with the results from the full ETF calculation with the optimized empirical data set of Table I. It is clear from the figure that within the uncertainties of the empirical parameters, our model predicts neutron skins compatible with experimental results, with a comparable level of precision as complete ETF calculations [47].…”

Section: Radii and Skinssupporting

confidence: 58%

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Constraints on the nuclear equation of state from nuclear masses and radii in a Thomas-Fermi meta-modeling approach

et al. 2017

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The question of correlations among empirical equation of state (EoS) parameters constrained by nuclear observables is addressed in a fully empirical meta-modeling approach. A recently proposed meta-modeling for the nuclear EoS in nuclear matter, is augmented with a single finite size term to produce a minimal unified EoS functional able to describe the smooth part of the nuclear ground state properties. This meta-model can reproduce the predictions of a large variety of models, and interpolate continuously between them. The parameter space is sampled and filtered through the constraint of nuclear mass reproduction. We show that this simple analytical meta-modeling has a predictive power on masses, radii, and skins comparable to full HF or ETF calculations with realistic energy functionals. The covariance analysis on the posterior distribution shows that no physical correlation is present between the different EoS parameters. Concerning nuclear observables, a strong correlation between the slope of the symmetry energy and the neutron skin is observed, in agreement with previous studies.

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Section: Radii and Skinssupporting

confidence: 58%

“…However, other correlations shown in the literature with E sym or K sym [11,47] are not observed here, which might again indicate the model dependence of these correlations.…”

Section: B Correlationssupporting

confidence: 46%

Constraints on the nuclear equation of state from nuclear masses and radii in a Thomas-Fermi meta-modeling approach

et al. 2017

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“…A polytropic EOS of N = 0 or 1 is usually used, while the resulting timescales for these two polytropic EOSs differ only by roughly a factor of two (we refer to a review by Andersson et al (2001) and references therein). The effects of more realistic EOSs have been tested by Papazoglou & Moustakidis (2016), whose results show only small differences from those of the N = 1 polytropic EOS. Following Alford et al (2012a,b), we consider the Akmal-Pandharipande-Ravenhall (APR) EOS (Akmal et al 1998), since this EOS gives a better approximation of the equilibrium configuration than the polytropic EOSs for r-mode oscillations.…”

Section: Gravitational Radiation and Viscositiesmentioning

confidence: 99%

Evolution of newborn rapidly rotating magnetars: Effects ofR-mode and fall-back accretion

Wang

Dai

2017

A&A

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In this paper we investigate effects of the r-mode instability on a newborn rapidly-rotating magnetar with fall-back accretion. Such a magnetar could usually occur in core-collapse supernovae and gamma-ray bursts. We find that the magnetar's spin and r-mode evolution are influenced by accretion. If the magnetar is sufficiently spun up to a few milliseconds, gravitational radiation leads to the growth of the r-mode amplitude significantly. The maximum r-mode amplitude reaches an order ∼ 0.001 when the damping due to the growth of a toroidal magnetic field balances the growth of the r-mode amplitude. If such a sufficiently spun-up magnetar was located at a distance less than 1 Mpc, then gravitational waves would be detectable by the Einstein Telescope but would have an extremely low event rate. However, if the spin-up is insufficient, the growth of the r-mode amplitude is mainly due to the accretion torque. In this case, the maximum r-mode amplitude is of the order of ∼ 10 −6 − 10 −5 .

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“…The energy density functional is an extension to the above formula, where the total energy of finite nuclei is a functional of the total density ρ(r) and the isospin asymmetry function α(r) [1],…”

mentioning

confidence: 99%

“…Instead of solving this differential equation, we are using a trial function given by the Fermi-type formula [1]…”

mentioning

confidence: 99%

Nuclear Symmetry Energy Effects on the Bulk Properties of Neutron-rich Finite Nuclei

Divaris

Moustakidis²

2020

hnps

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We systematically study the effect of the nuclear symmetry energy in the basic properties of finite, neutron-rich, heavy nuclei where symmetry energy plays a dominant role. We employ a variational method, in the framework of the Thomas-Fermi approximation, to study the effect of the symmetry energy on the neutron skin thickness and symmetry energy coefficients of various nuclei. The isospin asymmetry function a(r) is directly related to the symmetry energy as a consequence of the variational principle. In addition to this, the Coulomb interaction is included in a self-consistent way. The energy density of the asymmetric nuclear matter that is used, has its origins in a momentum-dependent interaction.

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Effects of the symmetry energy on the isovector properties of neutron-rich nuclei within a Thomas-Fermi approach

Cited by 5 publications

References 90 publications

Constraints on the nuclear equation of state from nuclear masses and radii in a Thomas-Fermi meta-modeling approach

Constraints on the nuclear equation of state from nuclear masses and radii in a Thomas-Fermi meta-modeling approach

Evolution of newborn rapidly rotating magnetars: Effects ofR-mode and fall-back accretion

Nuclear Symmetry Energy Effects on the Bulk Properties of Neutron-rich Finite Nuclei

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