Color superconducting matter in a magnetic field

Abstract

We investigate the effect of a magnetic field on cold dense three-flavor quark matter using an effective model with four-Fermi interactions with electric and color neutrality taken into account. The gap parameters Delta1, Delta2, and Delta3 representing respectively the predominant pairing between down and strange (d-s) quarks, strange and up (s-u) quarks, and up and down (u-d) quarks, show the de Haas-van Alphen effect, i.e. oscillatory behavior as a function of the modified magnetic field B that can penetrate the color superconducting medium. Without applying electric and color neutrality we find Delta2 ≈ Delta3 >> Delta1 for 2 e B / muq2, where e is the modified electromagnetic coupling constant and muq is one third of the baryon chemical potential. Because the average Fermi surface for each pairing is affected by taking into account neutrality, the gap structure changes drastically in this case; we find Delta1 >> Delta2 ≈ Delta3 for 2 e B > muq2. We point out that the magnetic fields as strong as presumably existing inside magnetars might induce significant deviations from the gap structure Delta1 ≈ Delta2 ≈ Delta3 at zero magnetic field.