Bridging Hubbard Model Physics and Quantum Hall Physics in Graphene Moire Superlattices

This thesis is focused on the strongly correlated physics of graphene moiré super-lattices formed in twisted bilayer graphene (TBG), twisted double bilayer graphene (TDBG) and ABC trilayer graphene aligned with hexagon boron nitride (TLG-hBN). First, I will show that the physics of these systems can be divided into two categories: (1)The nearly-flat bands have non-zero valley Chern number, which leads to "quantum Hall physics" including integer and fractional quantum anomalous Hall effect and composite fermi liquid (CFL) physics. (2) The narrow bands have trivial band topology. In this case the essential physics is captured by a Hubbard like lattice model similar to that of the high cuprates. Both of the above two classes have already been realized in the experiments. I will discuss how current and future experiments on these moiré materials can deepen our understanding of the cuprate physics and quantum Hall physics. In addition, I will also propose several new phases in moiré systems, which have never been studied before. These include featureless and orthogonal pseudogap metals and quantum Hall spin liquids. Copies available exclusively from MIT Libraries, libraries.mit.edu/docs|[email protected]