Classification of massive and gapless phases in bilayer graphene

Abstract

We here classify of all the fully gapped massive and gapless phases in bilayer graphene. The effective low energy theory in bilayer graphene is constructed, and various discrete and continuous symmetries of the non-interacting system is analyzed. Spinless fermions, placed in a quantizing magnetic field is considered. The quantum anomalous Hall insulator is properly defined. Constructing a particle-hole doubled 16 component Nambu-Dirac spinor, we recognize all the possible fully gapped, and the gapless states, which, on the other hand, split the parabolic dispersion into two anisotropic Dirac like conical ones. A thorough symmetry analysis of all the ordered states is performed. Altogether there are 8 insulating and 4 superconducting phases in bilayer graphene, that can lead to fully gapped spectrum. Among the gapped superconductors, three are spin-singlet, which include uniform s-wave and two spatially inhomogeneous, translational symmetry breaking Kekule superconductors. The triplet pairing exhibits an f-wave symmetry. Besides the gapped phases, there are 8 semimetallic and 8 gapless superconducting states in total, available for fermions to condense into. We also find novel gapless superconducting states, which break the translational symmetry, dubbed as gapless-Fulde-Farrell-Larkin-Ovchinikov superconductors. We also discuss the role of Coulomb interaction, and propose various experimental tools to determine the underlying ordered states.