Omar Benhar, Giulia De Rosi, Giovanni Salvi
Published 2013-05-20, updated 2017-05-18Version 2
Correlated basis function perturbation theory and the formalism of cluster expansions have been recently employed to obtain an effective interaction from a state-of-the-art nuclear Hamiltonian. We report the results of a study of the superfluid gap in pure neutron matter, associated with formation of Cooper pairs in the $^1S_0$ sector. The calculations have been carried out using an improved version of the CBF effective interaction, in which three-nucleon forces are taken into account using a realistic microscopic model. Our results show that the superfluid transition occurs at densities corresponding to the neutron star inner crust, and that inclusion of three-nucleon interactions leads to a sizable reduction of the energy gap at the Fermi surface.
Comments: A new paper on the same subject, and a different set of authors, has been submitted
Neutron star inner crust: effects of rotation and magnetic fields
The role of the boundary conditions in the Wigner-Seitz approximation applied to the neutron star inner crust
Role of the boundary conditions in the Wigner-Seitz approximation applied to the neutron star inner crust
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