Ferromagnetism in Correlated Electron Systems: Generalization of Nagaoka's Theorem
Abstract
Nagaoka's theorem on ferromagnetism in the Hubbard model with one electron less than half filling is generalized to the case where all possible nearest-neighbor Coulomb interactions (the density-density interaction V, bond-charge interaction X, exchange interaction F, and hopping of double occupancies F') are included. It is shown that for ferromagnetic exchange coupling (F>0) ground states with maximum spin are stable already at finite Hubbard interaction U>Uc. For non-bipartite lattices this requires a hopping amplitude t≤0. For vanishing F one obtains Uc∞ as in Nagaoka's theorem. This shows that the exchange interaction F is important for stabilizing ferromagnetism at finite U. Only in the special case X=t the ferromagnetic state is stable even for F=0, provided the lattice allows the hole to move around loops.
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