Ferromagnetism beyond Lieb's theorem

Abstract

The noninteracting electronic structures of tight binding models on bipartite lattices with unequal numbers of sites in the two sublattices have a number of unique features, including the presence of spatially localized eigenstates and flat bands. When a uniform on-site Hubbard interaction U is turned on, Lieb proved rigorously that at half filling (=1) the ground state has a non-zero spin. In this paper we consider a `CuO2 lattice (also known as `Lieb lattice', or as a decorated square lattice), in which `d-orbitals' occupy the vertices of the squares, while `p-orbitals' lie halfway between two d-orbitals. We use exact Determinant Quantum Monte Carlo (DQMC) simulations to quantify the nature of magnetic order through the behavior of correlation functions and sublattice magnetizations in the different orbitals as a function of U and temperature. We study both the homogeneous (H) case, Ud= Up, originally considered by Lieb, and the inhomogeneous (IH) case, Ud≠ Up. For the H case at half filling, we found that the global magnetization rises sharply at weak coupling, and then stabilizes towards the strong-coupling (Heisenberg) value, as a result of the interplay between the ferromagnetism of like sites and the antiferromagnetism between unlike sites; we verified that the system is an insulator for all U. For the IH system at half filling, we argue that the case Up≠ Ud falls under Lieb's theorem, provided they are positive definite, so we used DQMC to probe the cases Up=0,Ud=U and Up=U, Ud=0. We found that the different environments of d and p sites lead to a ferromagnetic insulator when Ud=0; by contrast, Up=0 leads to to a metal without any magnetic ordering. In addition, we have also established that at density =1/3, strong antiferromagnetic correlations set in, caused by the presence of one fermion on each d site.