• Citer

Effect of BCS pairing on entrainment in neutron superfluid current in neutron star crust

par Carter, Brandon D.;Chamel, Nicolas ;Haensel, Pawel
Référence Nuclear physics. A, 759, 3-4, page (441-464)
Publication Publié, 2005-06-09

Article révisé par les pairs

• Accès en ligne
• Détails
• Contenu
• Statistiques

Résumé :

The relative current density ni of "conduction" neutrons in a neutron star crust beyond the neutron drip threshold can be expected to be related to the corresponding particle momentum covector pi by a linear relation of the form ni = Kij pj in terms of a physically well-defined mobility tensor Kij. This result is describable as an "entrainment" whose effect - wherever the crust lattice is isotropic - will simply be to change the ordinary neutron mass m to a "macroscopic" effective mass m* such that in terms of the relevant number density n of unconfined neutrons we shall have Kij = (n/m*) γij. In a preceding work based on a independent particle treatment beyond the Wigner-Seitz approximation, using Bloch type boundary conditions to obtain the distribution of energy Ek and associated group velocity vk i = ∂ Ek/∂ E ki as a function of wave vector ki, it was shown that the mobility tensor would be proportional to a phase space volume integral Kij ∝ ∫ d3k vk i vk j δ {Ek - μ}, where μ is the Fermi energy. Using the approach due to Bogoliubov, it is shown here that the effect of BCS pairing with a superfluid energy gap ΔF and corresponding quasiparticle energy function €k = √(Ek - μ)2 + ΔF 2 will just be to replace the Dirac distributional integrand by the smoother distribution in the formula Kij ∝ ∫ d3k vk i vk j ΔF 2/ €k 3. It is also shown how the pairing condensation gives rise to superfluidity in the technical sense of providing (meta) stability against resistive perturbations for a current that is not too strong (its momentum pi must be small enough to give 2 pivk i < €k 2/ Ek - μ for all modes). It is concluded that the prediction of a very large effective mass enhancement in the middle layers of the star crust will not be significantly effected by the pairing mechanism. © 2005 Elsevier B.V. All rights reserved.