Multi-orbital physics of edge-magnetism in a Hubbard model of transition-metal dichalcogenide nanoribbons: Comparing Mean Field Theory and Determinant Quantum Monte Carlo

Abstract: We study the emergence of edge-magnetism in zigzag nanoribbons from electron-electron interactions in a minimal 3-band tight-binding descrip¬tion of transition-metal dichalcogenide monolayers with an intra-orbital Hub¬bard term. We explain the influence of each orbital in the magnetic ordering, comparing the results of Mean Field Theory and determinant Quantum Monte Carlo. We focus on a gapped edge-antiferromagnetic phase appearing at three-quarter edge-filling for realistic values of the interaction.

“…The effective Hubbard model for monolayer graphene with on-site interaction was proposed [ 23 ], suggesting that large isotropic strain may drive this system from semimetallic towards the Mott-insulating phase [ 24 , 25 ] in analogy with high pressure changing properties of various bulk materials [ 26 , 27 , 28 , 29 , 30 ]. The effects of electron correlations are usually more pronounced in graphene nanosystems, where quantum fluctuations are reduced and magnetic moments may form near free edges [ 31 , 32 , 33 ] (although defining metallic and insulating states for a nanosystem is more cumbersome than for a bulk system [ 34 , 35 ]). We further notice that artificial graphene-like systems allow one to tune the interaction in a wider range than actual graphene [ 36 , 37 , 38 , 39 ].…”

Mott Transition in the Hubbard Model on Anisotropic Honeycomb Lattice with Implications for Strained Graphene: Gutzwiller Variational Study

“…The effective Hubbard model for monolayer graphene with on-site interaction was proposed [ 23 ], suggesting that large isotropic strain may drive this system from semimetallic towards the Mott-insulating phase [ 24 , 25 ] in analogy with high pressure changing properties of various bulk materials [ 26 , 27 , 28 , 29 , 30 ]. The effects of electron correlations are usually more pronounced in graphene nanosystems, where quantum fluctuations are reduced and magnetic moments may form near free edges [ 31 , 32 , 33 ] (although defining metallic and insulating states for a nanosystem is more cumbersome than for a bulk system [ 34 , 35 ]). We further notice that artificial graphene-like systems allow one to tune the interaction in a wider range than actual graphene [ 36 , 37 , 38 , 39 ].…”

Mott Transition in the Hubbard Model on Anisotropic Honeycomb Lattice with Implications for Strained Graphene: Gutzwiller Variational Study