Correlated Superconducting and Insulating States in Twisted Trilayer Graphene Moire of Moire Superlattices

Layers of two-dimensional materials stacked with a small twist-angle give rise to beating periodic patterns on a scale much larger than the original lattice, referred to as a "moire superlattice". When the stacking involves more than two layers with independent twist angles between adjacent layers it generates "moire of moire" superlattices, with multiple length scales that control the system's behavior. Here, we demonstrate these effects of a high-order moire superlattice in twisted trilayer graphene with the twist angles chosen to be equal, at ~ 3.06 degree. We report superconducting and correlated insulating states near the half filling of the moire of moire superlattice at a carrier density (~ 10^10 cm^-2) significantly lower than any previously-reported superconductor. Moreover, the temperature dependence of the measured resistances at full-occupancy (v = -4 and v = 4) states are semi-metallic, distinct from the insulating behavior of the twisted bilayer systems, providing a first demonstration of emergent superconductivity from single-particle states that correspond to continuous, non-isolated flat-bands. Compared to twisted bilayer graphene (tBLG), we find robust superconductivity with Tc ~ 3.4 K despite the extremely low carrier density. Our findings imply that phonons may play a bigger role than flat bands and singular density of states in bringing about the correlated behavior.