Observation of re-entrant correlated insulators and interaction driven Fermi surface reconstructions at one magnetic flux quantum per moir\'e unit cell in magic-angle twisted bilayer graphene

The discovery of flat bands with non-trivial band topology in magic angle twisted bi-layer graphene (MATBG) has provided a unique platform to study strongly correlated phe-nomena including superconductivity, correlated insulators, Chern insulators and magnetism. A fundamental feature of the MATBG, so far unexplored, is its high magnetic field Hof-stadter spectrum. Here we report on a detailed magneto-transport study of a MATBG de-vice in external magnetic fields of up to B = 31 T, corresponding to one magnetic flux quan-tum per moir\'e unit cell {\Phi}0. At {\Phi}0, we observe a re-entrant correlated insulator at a flat band filling factor of {\nu} = +2, and interaction-driven Fermi surface reconstructions at other fillings, which are identified by new sets of Landau levels originating from these. These ex-perimental observations are supplemented by theoretical work that predicts a new set of 8 well-isolated flat bands at {\Phi}0 , of comparable band width but with different topology than in zero field. Overall, our magneto-transport data reveals a qualitatively new Hofstadter spec-trum in MATBG, which arises due to the strong electronic correlations in the re-entrant flat bands.