Band magnetism in the Hubbard model

Abstract

A self-consistent moment method is applied to the Hubbard model in order to find out under what circumstances spontaneous band magnetism may occur. The theory is formulated for a two-sublattice structure to treat simultaneously para-, ferro-, and antiferromagnetic systems. The starting point is a two-pole ansatz for the one-electron spectral density, the free parameters of which are fitted by equating exactly calculated spectral moments. All correlation functions appearing in the moments can be expressed by the spectral density, guaranteeing therewith a closed system of equations, which can be solved self-consistently for the average particle numbers 〈$n_{i\uparrow }$〉 and 〈$n_{i\downarrow }$〉. A T=0 phase diagram is presented in terms of band occupation n (0≤n≤2) and Coulomb interaction U. Ferromagnetic solutions appear only if n exceeds a critical occupation $n_c^{\mathrm{FM}}$ and U a minimum value $U_{\min }$. For antiferromagnetic solutions a critical U does not exist, but a critical band occupation $n_c^{\mathrm{AFM}}$ does.