2006
DOI: 10.1103/physrevc.74.068801
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Ferromagnetic instabilities in neutron matter at finite temperature with the Gogny interaction

Abstract: 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 ne… Show more

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Cited by 28 publications
(33 citation statements)
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“…(38) shows that the inclusion of the tensor interaction results always in a smaller value for the critical density than the one without tensor terms, and consequently the spontaneous magnetization would appear at densities closer to ρ 0 . In the next subsection we shall show that neither finite-range effective interactions [25] nor realistic calculations [26] predict such a spontaneous magnetization in neutron matter, which therefore should be considered as an artifact of the Skyrme interaction.…”
Section: A Skyrme Interactionsmentioning
confidence: 94%
“…(38) shows that the inclusion of the tensor interaction results always in a smaller value for the critical density than the one without tensor terms, and consequently the spontaneous magnetization would appear at densities closer to ρ 0 . In the next subsection we shall show that neither finite-range effective interactions [25] nor realistic calculations [26] predict such a spontaneous magnetization in neutron matter, which therefore should be considered as an artifact of the Skyrme interaction.…”
Section: A Skyrme Interactionsmentioning
confidence: 94%
“…The Gogny mean-field cannot be separated cleanly into an effective mass and a momentum independent term. This separation might eventually be performed as an additional approximation and, on the whole, should provide reasonable results [52]. However, full mean-field calculations are preferable for accurate calculations of liquid-gas coexistence curves.…”
Section: Self-consistent Mean-field Calculations Of Hot Nuclear Mattermentioning
confidence: 99%
“…[9] the consideration also has been done for the Gogny effective NN interaction (D1S, D1P parametrizations) up to densities 4̺ 0 . Since for the D1S parametrization there is no spontaneous ferromagnetic transition in neutron matter for all relevant densities, and for the D1P parametrization this transition occurs at the density larger than 7̺ 0 [23], no sign of a ferromagnetic transition at a strong magnetic field was found in Ref. [9] up to densities 4̺ 0 for these Gogny forces.…”
Section: Discussionmentioning
confidence: 96%
“…On the one hand, the models with the Skyrme effective nucleonnucleon (NN) interaction predict the occurrence of spontaneous spin instability in nuclear matter at densities in the range from ̺ 0 to 4̺ 0 for different parametrizations of the NN potential [10]- [22] (̺ 0 = 0.16 fm −3 is the nuclear saturation density). For the Gogny effective interaction, a ferromagnetic transition in neutron matter occurs at densities larger than 7̺ 0 for the D1P parametrization and is not allowed for D1, D1S parametrizations [23]. However, for the D1S Gogny force an antiferromagnetic phase transition happens in symmetric nuclear matter at the density 3.8̺ 0 [24].…”
Section: Introductionmentioning
confidence: 97%