TSTG II: Projected Hartree-Fock Study of Twisted Symmetric Trilayer Graphene

Abstract

The Hamiltonian of the magic-angle twisted symmetric trilayer graphene (TSTG) can be decomposed into a TBG-like flat band Hamiltonian and a high-velocity Dirac fermion Hamiltonian. We use Hartree-Fock mean field approach to study the projected Coulomb interacting Hamiltonian of TSTG developed in Calugaru et al. [Phys. Rev. B 103, 195411 (2021)] at integer fillings =-3, -2, -1 and 0 measured from charge neutrality. We study the phase diagram with w0/w1, the ratio of AA and AB interlayer hoppings, and the displacement field, which introduces an interlayer potential U and hybridizes the TBG-like bands with the Dirac bands. At small U, we find the ground states at all fillings are in the same phases as the tensor products of a Dirac semimetal with the filling TBG insulator ground states, which are spin-valley polarized at =-3, and fully (partially) intervalley coherent at =-2,0 (=-1) in the flat bands. An exception is =-3 with w0/w1 0.7, which possibly become a metal with competing orders at small U due to charge transfers between the Dirac and flat bands. At strong U where the bandwidths exceed interactions, all the fillings enter a metal phase with small or zero valley polarization and intervalley coherence. Lastly, at intermediate U, semimetal or insulator phases with zero intervalley coherence may arise for =-2,-1,0. Our results provide a simple picture for the electron interactions in TSTG systems, and reveal the connection between the TSTG and TBG ground states.

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