The interplay of field-tunable strongly correlated states in a multi- orbital moiré system

AJ Campbell and V Vitale and M Brotons-Gisbert and H Baek and A Borel and TV Ivanova and T Taniguchi and K Watanabe and J Lischner and BD Gerardot, NATURE PHYSICS, 20 (2024).

DOI: 10.1038/s41567-024-02385-4

The interplay of charge, spin, lattice and orbital degrees of freedom leads to a variety of emergent phenomena in strongly correlated systems. In transition-metal-dichalcogenide-based moire heterostructures, recent observations of correlated phases can be described by triangular-lattice single-orbital Hubbard models based on moire bands derived from the Brillouin-zone corners-the so-called K valleys. Richer phase diagrams described by multi-orbital Hubbard models are possible with hexagonal lattices that host moire bands at the zone centre-called Gamma valleys- or an additional layer degree of freedom. Here we report the tunable interaction between strongly correlated hole states hosted by Gamma- and K-derived bands in a heterostructure of monolayer MoSe2 and bilayer 2H WSe2. We characterize the behaviour of exciton-polarons to distinguish the layer and valley degrees of freedom. The Gamma band gives rise to a charge-transfer insulator described by a two-orbital Hubbard model. An out-of-plane electric field re-orders the Gamma- and K-derived bands and drives the redistribution of carriers to the layer-polarized K orbital, generating Wigner crystals and Mott insulating states. Finally, we obtain degeneracy of the Gamma and K orbitals at the Fermi level and observe interacting correlated states with phase transitions dependent on the doping density. Our results establish a platform to investigate multi-orbital Hubbard model Hamiltonians. Heterostructures of transition metal dichalcogenides are known to simulate the triangular-lattice Hubbard model. Now, by combining a monolayer and bilayer of different materials, this idea is extended to multi-orbital Hubbard models.

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