Ferromagnetism of dense neutron matter

Dąbrowski, Janusz; Piechocki, Włodzimierz; Rożynek, J.; Haensel, P.

doi:10.1103/physrevc.17.1516

Cited by 20 publications

(23 citation statements)

References 9 publications

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“…When introducing isospin asymmetry in the nuclear medium a splitting of the single-particle potentials occurs due to the strong isospin dependence of the ΣN interaction. The splittings among the Σ + , Σ 0 and Σ − potentials as obtained in our microscopic calculation have a nonlinear dependence on the isospin asymmetry which goes beyond the usual (linear) parametrization in terms of an isovector Lane potential [82].…”

Section: Resultsmentioning

confidence: 64%

Hyperons in nuclear matter from SU(3) chiral effective field theory

et al. 2016

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Brueckner theory is used to investigate the properties of hyperons in nuclear matter. The hyperon-nucleon interaction is taken from chiral effective field theory at next-to-leading order with SU(3) symmetric low-energy constants. Furthermore, the underlying nucleon-nucleon interaction is also derived within chiral effective field theory. We present the single-particle potentials of Λ and Σ hyperons in symmetric and asymmetric nuclear matter computed with the continuous choice for intermediate spectra. The results are in good agreement with the empirical information. In particular, our calculation gives a repulsive Σ-nuclear potential and a weak Λ-nuclear spin-orbit force.

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Section: Resultsmentioning

confidence: 64%

Hyperons in nuclear matter from SU(3) chiral effective field theory

et al. 2016

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“…On the contrary, it has not been possible to prove without any ambiguity the existence of Σ-hypernuclei (see e.g., Refs. [18,19,20,21,22,23,24,25,26]) which suggest that the Σ-nucleon interaction is most probably repulsive [27,28,29,30,31,32,33,34,35,36].…”

Section: Introductionmentioning

confidence: 99%

Single-particle spectral function of the Λ hyperon in finite nuclei

Vidaña¹

2019

AIP Conference Proceedings

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The spectral function of the Λ hyperon in finite nuclei is calculated from the corresponding Λ self-energy, which is constructed within a perturbative many-body approach using some of the hyperon-nucleon interactions of the Jülich and Nijmegen groups. Binding energies, wave functions and disoccupation numbers of different single-particle states are obtained for various hypernuclei from 5 Λ He to 209 Λ Pb. The agreement between the calculated binding energies and experimental data is qualitatively good. The small spin-orbit splitting of the p−, d−, f − and g−wave states is confirmed. The discrete and the continuum contributions of the single-Λ spectral function are computed. Their appearance is qualitatively similar to that of the nucleons. The Z-factor, that measures the importance of correlations, is also calculated. Our results show that its value is relatively large, indicating that the Λ hyperon is less correlated than nucleons. This is in agreement with the results obtained by other authors for the correlations of the Λ in infinite nuclear matter. The disoccupation numbers are obtained by integrating the spectral function over the energy. Our results show that the discrete contribution to the disoccupation number decreases when increasing the momentum of the Λ. This indicates that, in the production reactions of hypernuclei, the Λ hyperon is mostly formed in a quasi-free state.

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“…The possible existence of a phase transition of neutron matter to a ferromagnetic state has motivated many investigations of the equation of state (EOS) of spin-polarized neutron matter. In addition to the interest that such a transition could have in the context of neutron stars [1], this problem has gained interest in itself and has been addressed in the framework of very different theoretical approaches [2][3][4][5][6][7][8][9][10][11]. Whereas some of these calculations, like for instance those based on Skyrme-like interactions, predict a transition at densities in the range (1 − 4)ρ 0 (with ρ 0 = 0.16 fm −3 the saturation density of symmetric nuclear matter), others, like recent Monte Carlo [7] or Brueckner-Hartree-Fock (BHF) calculations [9,10] using modern two-and three-body realistic interactions, exclude such a transition at least up to densities around five times ρ 0 .…”

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Ferromagnetic instabilities in neutron matter at finite temperature with the Gogny interaction

et al. 2006

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The properties of spin-polarized neutron matter are studied both at zero and finite temperature using the D1 and the D1P parametrizations of the Gogny interaction. The results show two different behaviors: whereas the D1P force exhibits a ferromagnetic transition at a density of ρ c ∼ 1.31 fm −3 whose onset increases with temperature, no sign of such a transition is found for D1 at any density and temperature, in agreement with recent microscopic calculations. The possible existence of a phase transition of neutron matter to a ferromagnetic state has motivated many investigations of the equation of state (EOS) of spin-polarized neutron matter. In addition to the interest that such a transition could have in the context of neutron stars [1], this problem has gained interest in itself and has been addressed in the framework of very different theoretical approaches [2][3][4][5][6][7][8][9][10][11]. Whereas some of these calculations, like for instance those based on Skyrme-like interactions, predict a transition at densities in the range (1 − 4)ρ 0 (with ρ 0 = 0.16 fm −3 the saturation density of symmetric nuclear matter), others, like recent Monte Carlo [7] or Brueckner-Hartree-Fock (BHF) calculations [9,10] using modern two-and three-body realistic interactions, exclude such a transition at least up to densities around five times ρ 0 . In spite of this discrepancy, it is interesting to study how temperature influences the ferromagnetic transition [12,13]. In Ref. DOI[12] an analysis of the temperature effects in the framework of a Hartree-Fock calculation with Skyrme interactions was performed. In the present Brief Report, we study the influence of the finite-range terms of the interaction on the ferromagnetic transition. To this end, we consider the Gogny interaction. This is an effective nucleon-nucleon force with both zero-and finite-range terms and a simple spin-isospin structure. In addition to the original D1 parametrization [14], several other parametrizations of this force are available. The D1S force, for instance, was introduced to improve the pairing properties and surface effects of finite nuclei [15], whereas more recently the D1P [16] interaction has been introduced with the aim of reproducing the EOS of pure neutron matter given by a variational microscopic calculation with realistic interactions [17].The properties of nuclear matter deduced from Gogny interactions have already been treated in the literature [18]. Indeed, several instabilities produced by these forces at zero temperature have been studied in previous works [19]. The isospin instability, for instance, is a common feature to all the existing Gogny parametrizations as well as of most Skyrme forces. This instability is signaled by the fact that, above a certain critical density, the energy per particle of nuclear matter becomes more repulsive than that of neutron matter. For the D1P force, this instability takes place at ρ I ∼ 7ρ 0 , whereas for D1 it occurs at ρ I ∼ 3ρ 0 . Furthermore, D1 and D1S also exhibit a spinodal instability in...

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Ferromagnetism of dense neutron matter

Cited by 20 publications

References 9 publications

Hyperons in nuclear matter from SU(3) chiral effective field theory

Hyperons in nuclear matter from SU(3) chiral effective field theory

Single-particle spectral function of the Λ hyperon in finite nuclei

Ferromagnetic instabilities in neutron matter at finite temperature with the Gogny interaction

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