Symmetry protected vortex bound state in superfluid 3He B-phase

Abstract

The superfluid 3He formed by spin-triplet p-wave Cooper pairs is a typical topological superfluid. In the superfluid 3He B-phase, several kinds of vortices classified by spatial symmetries P1, P2, and P3 are produced, where P1 is inversion symmetry, P2 is magnetic reflection symmetry, and P3 is magnetic π-rotation symmetry. We have calculated the vortex bound states by the Bogoliubov-de Gennes theory and the quasiclassical Eilenberger theory, and also clarified symmetry protection of the low energy excitations by the spatial symmetries. On the symmetry protection, P3 symmetry plays a key role which gives two-fold degenerate Majorana zero modes. Then, the bound states in the most symmetric o vortex with P1, P2, and P3 symmetries and in w vortex with P3 symmetry have the symmetry protected degenerate Majorana zero modes. On the other hand, zero energy modes in v vortex, which is believed to be realized in the actual B-phase, are not protected, and in consequence become gapped by breaking axial symmetry. The excitation gap may have been observed as the variation of critical velocity. We have also suggested an experimental setup to create o vortex with Majorana zero modes by a confinement and a magnetic field.