Mean-field phase diagram of negative-U Hofstadter-Hubbard model
ORAL
Abstract
It has been predicted that topological superconductivity supporting Majorana quasiparticles can
be produced by proximity coupling the Dirac metal at the surface of a topological insulator to an
ordinary superconductor, effectively giving rise to p-wave superconductivity. We investigate here
the phase diagram of a p-wave superconductor in two dimensions, modeled as a system of spinless
electrons on a lattice with nearest neighbor attractive interaction, exposed to a magnetic field. We
solve the mean-field Bogoliubov-de Gennes equations, in both the pairing and density channels, in
a self-consistent, gauge-invariant fashion. We find that as the interaction strength is increased, the
system first makes a transition from a quantum Hall phase to a skyrmion lattice phase that is fully
gapped in the bulk but has topological chiral edge current, followed by a vortex phase in which
either the vortices form a lattice with one vortex per unit cell, and the fermionic spectrum contains
a low-energy Majorana band, or the vortices form dimers with two vortices per unit cell, and the
low-energy band is gapped. The observable consequences of skyrmions as well as Majorana fermions
are indicated.
be produced by proximity coupling the Dirac metal at the surface of a topological insulator to an
ordinary superconductor, effectively giving rise to p-wave superconductivity. We investigate here
the phase diagram of a p-wave superconductor in two dimensions, modeled as a system of spinless
electrons on a lattice with nearest neighbor attractive interaction, exposed to a magnetic field. We
solve the mean-field Bogoliubov-de Gennes equations, in both the pairing and density channels, in
a self-consistent, gauge-invariant fashion. We find that as the interaction strength is increased, the
system first makes a transition from a quantum Hall phase to a skyrmion lattice phase that is fully
gapped in the bulk but has topological chiral edge current, followed by a vortex phase in which
either the vortices form a lattice with one vortex per unit cell, and the fermionic spectrum contains
a low-energy Majorana band, or the vortices form dimers with two vortices per unit cell, and the
low-energy band is gapped. The observable consequences of skyrmions as well as Majorana fermions
are indicated.
–
Presenters
-
Jonathan Schirmer
Pennsylvania State University
Authors
-
Jonathan Schirmer
Pennsylvania State University
-
Jainendra K Jain
Pennsylvania State University
-
Chaoxing Liu
Pennsylvania State University, Department of physics, Pennsylvania State University