Dumitru Calugaru1,Nicolas Regnault1,Myungchul Oh1,Kevin Nuckolls1,Dillon Wong1,Ryan Lee1,Ali Yazdani1,Oskar Vafek2,3,Bogdan Bernevig1,4,5
Princeton University1,National High Magnetic Field Laboratory2,Florida State University3,Donostia International Physics Center4,IKERBASQUE5
Dumitru Calugaru1,Nicolas Regnault1,Myungchul Oh1,Kevin Nuckolls1,Dillon Wong1,Ryan Lee1,Ali Yazdani1,Oskar Vafek2,3,Bogdan Bernevig1,4,5
Princeton University1,National High Magnetic Field Laboratory2,Florida State University3,Donostia International Physics Center4,IKERBASQUE5
<br/>We calculate STM signatures of correlated ground-states at integer filling of the magic angle twisted bilayer graphene narrow bands. First, we compute the fully-interacting TBG spectral function at ±4 electrons/moiré unit cell and show that it can be used to experimentally validate the strong-coupling approach. Although variation exists in the data, we find experimental evidence for the strong-coupling regime. For all other integer fillings of the flat bands, we consider the spatial features of the corresponding spectral functions of many states in the large degenerate ground-state manifold, and assess the possibility of Kekulé distortion (KD) emerging at the graphene lattice scale. Remarkably, we find that coupling the two opposite graphene valleys in the intervalley-coherent (IVC) TBG insulators does not always result in KD. As an example, we show that the K-IVC state and all its nonchiral U(4) rotations do not exhibit any KD, while T-IVC does. We analyze 14 different many-body correlated states and show that their combined STM/Chern number signal can be used to uniquely determine the nature of the many-body ground-state. Their STM signal and features are obtained over a large range of energies and model parameters.