Infrared spectroscopy of phase transitions in the lowest Landau levels of bilayer graphene

We perform infrared magneto-spectroscopy of Landau level (LL) transitions in dual-gated bilayer graphene. At $\nu=4$ when the zeroth LL (octet) is filled, two resonances are observed indicating the opening of a gap. At $\nu=0$ when the octet is half-filled, multiple resonances are found to disperse non-monotonically with increasing displacement field, $D$, perpendicular to the sheet, showing a phase transition at modest displacement fields to the layer-polarized state with a gap that opens linearly in $D$. When $D=0$ and $\nu$ is varied, resonances at $\pm\nu$ show an electron-hole asymmetry with multiple line splittings as the octet is progressively filled. Broadly these data show good agreement with predictions from a mean-field Hartree-Fock calculation, but only by accounting for multiple tight-binding terms in a four-band model of bilayer graphene that also incorporates valley interaction anisotropy. Our results are consistent with the presence of a canted anti-ferromagnet (CAFM) ground state at $\nu=0$, and imply the existence of intermediate phases in the transition from the CAFM to the layer-polarized regime.