Finite Temperature Strong Coupling Expansions for the SU(N) Hubbard Model

Abstract

We develop finite temperature strong coupling expansions for the SU(N) Hubbard Model in powers of β t, w=(-β U) and 1 β U for arbitrary filling. The expansions are done in the grand canonical ensemble and are most useful at a density of one particle per site, where for U larger than or of order the Bandwidth, the expansions converge over a wide temperature range t2/U \ \ T \ \ 10 U. By taking the limit w 0, valid at temperatures much less than U, the expansions turn into a high temperature expansion for a dressed SU(N) Heisenberg model that includes nearest-neighbor exchange, further neighbor exchanges and ring exchanges known from the T=0 perturbation theory of the SU(2) Hubbard model. Below a filling of one particle per site, the w 0 limit corresponds to an effective t-J model. The onset of strong correlations can be identified by a plateau-like behavior in the entropy as a function of temperature. At small deviations from one particle per site, the expansions can be arranged in powers of a small parameter δ=1-n, the deviation from one particle per site, where the leading β t dependent terms correspond to holes sloshing around in a disordered SU(N) background. We use these expansions to calculate the thermodynamic properties of the model at moderate and high temperatures over a wide parameter range.