Abstract
When one of the graphene layers of Magic Angle Twisted Bilayer Graphene is nearly aligned with its hexagonal boron nitride substrate (a configuration dubbed TBG/hBN), the active electronic bands are nearly flat, and have a Chern number $C=\pm1$. Recent experiments demonstrated a quantum anomalous Hall effect and spontaneous valley polarization at integer filling $\nu_T=3$ of the conduction band in this system. Motivated by this discovery, we ask whether fractional quantum anomalous Hall states (FQAH) could also emerge in TBG/hBN. We focus on the range of filling fractions where valley ferromagnetism was observed experimentally. Using exact diagonalization, we find that the ground states at $\nu_T = \frac{10}{3}$ and $\nu_T=\frac{17}{5}$ are fractional Chern insulator states in the flat band limit (in the hole picture, these are the fractional quantum Hall fractions $\frac{2}{3}$ and $\frac{3}{5}$). The ground state is either spin polarized or a spin singlet depending sensitively on band parameters. For nominally realistic band parameters, spin polarization is favored. Flattening the Berry curvature by changing a band parameter gives way to the spin singlet phase. Our estimation of the charge gap in the flat band limit shows that the FQAH state may be seen at accessible temperatures in experiments. We also study the effect of a non-zero bandwidth and show that there is a reasonable range of parameters in which the FQAH state is the ground state.
Highlights
Our estimation of the charge gap in the flatband limit shows that the FQAH state may be seen at accessible temperatures in experiments
We study the effect of a nonzero bandwidth and show that there is a reasonable range of parameters in which the FQAH state is the ground state
Both the numerical results of Ref. [76] and the analytical approach of Ref. [77] are in agreement with our findings where they overlap
Summary
The nearly flat bands of many moiré graphene materials are a platform for several fascinating many-body phenomena, including correlated insulators [1,2,3,4,5,6,7,8], superconductivity [2,4,5,6,7,9,10,11], ferromagnetism [6,7,8,12,13,14], and a (quantized) anomalous Hall effect [12,13,14]. The theoretical understanding of ferromagnetism in narrow bands of moiré systems has since expanded to include evidence from Hartree-Fock calculations [20,21,25,26,27,28,29], as well as exact diagonalization and density matrix renormalization group calculations [30] In this context, it is of tremendous interest to ask if TBG/hBN shows a fractional quantum anomalous Hall (FQAH) effect when the conduction band is doped away from integer filing. It is unknown how these multicomponent phenomena are influenced by the bandstructure properties relevant in FCIs, such as nonzero bandwidth and nontrivial Berry curvature distribution With these motivations, we study a model appropriate for TBG/h-BN and present evidence for a FQAH state at total band fillings. The PES confirms that it has the same topological order as the particle-hole conjugate of the Jain 2/5 state [61,62,63] (see Appendix B for further details)
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