The phase diagrams and superconducting properties of the extended Hubbard model with pair hopping interaction, i.e., the Penson-Kolb-Hubbard model are studied. The analysis of the model is performed for d-dimensional hypercubic lattices, including $d=1\mathrm{}$ and $d=\infty ,$ by means of the (broken symmetry) Hartree-Fock approximations and, for $d=\infty ,$ by the slave-boson mean-field method. For $d=1,$ at half filling the phase diagram is shown to consist of nine different phases including two superconducting states with center-of-mass momentum $q=0\mathrm{}$ and $q=Q$ $(\eta$ pairing), site and bond-located antiferromagnetic and charge-density wave states as well as three mixed phases with coexisting site and bond orderings. The stability range of the bond-type orderings shrinks with increasing lattice dimensionality d and for $d=\infty$ the corresponding diagram consists of four phases only, involving exclusively site-located orderings. Comparing the pair hopping model with the attractive Hubbard model we found in both cases gradual evolution from the BCS-like limit to the tightly bound pairs regime and a monotonic increase of the gap in the excitation spectrum with increasing coupling. However, the dynamics of electron pairs in both models is qualitatively different, which results in different dependences of condensation energies and critical temperatures on interaction parameters as well as in different electrodynamic properties, especially in a strong coupling regime.

• Received 29 May 1998

DOI:https://doi.org/10.1103/PhysRevB.59.6430