Recently, it has been discovered that when two graphene monolayers are stacked and twisted at 1.1o also known as a “magic angle”, superconductivity arises due to the long-range Moiré pattern that appears at these stacking angles. Here, interactions between electrons and their band topology give rise to novel quantum states of matter, such as strongly-correlated insulators and orbital ferromagnets, when tuning the carrier concentration with an external gate. Much of the underlying physics behind such states is yet to be understood, and the strong interactions present in these devices could be exploited to observe even more novel phenomena, making this van der Waals material an ideal platform to study and engineer new physics.
Additionally, recent reports have shown that in the naturally occurring Bernal (AB stacking) bilayer graphene, when applying an in-plane magnetic field superconductivity appears at carrier concentrations where no superconductivity would otherwise be present. This is in stark contrast to conventional superconductor theory, according to which magnetic fields destabilize and destroy superconductive states. Thus, both twisted and Bernal bilayer graphene are an ideal platform to study strong correlations, superconductivity, and how these quantum states are affected by strain.