The Metal-Insulator Transition in the Doubly Degenerate Hubbard Model

Abstract

A systematic study has been made on the metal-insulator (MI) transition of the doubly degenerate Hubbard model (DHM) in the paramagnetic ground state, by using the slave-boson mean-field theory which is equivalent to the Gutzwiller approximation (GA). For the case of infinite electron-electron interactions, we obtain the analytic solution, which becomes exact in the limit of infinite spatial dimension. On the contrary, the finite-interaction case is investigated by numerical methods with the use of the simple-cubic model with the nearest-neighbor hopping. The mass-enhancement factor, Z, is shown to increase divergently as one approaches the integer fillings (N = 1, 2, 3), at which the MI transition takes place, N being the total number of electrons. The calculated N dependence of Z is compared with the observed specific-heat coefficient, γ, of Sr1-xLaxTiO3 which is reported to significantly increase as x approaches unity.

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