Symmetry and spontaneous symmetry breaking of the Hubbard model on a square lattice ground state

Abstract

In this paper we consider the simplified form that a recently introduced general operator description of the Hubbard model on the square lattice with Na2 1 sites, effective transfer integral t, and onsite repulsion U has in a suitable one- and two-electron subspace. Such an operator description is that consistent with the model exact global symmetry recently extended to SO(3)× SO(3)× U(1). There is a large consensus that in the thermodynamic limit Na2→∞ long-range antiferromagnetic order occurs in the spin-density m=0 ground state of the half-filled Hubbard model on the square lattice. Here we find that the corresponding spontaneous symmetry breaking lowers the symmetry of such a state from SO(3)× SO(3)× U(1) for Na2 1 large but finite to [U(2)× U(1)]/Z22 [SO(3)× U(1)× U(1)]/Z2 for Na2→∞. Moreover, we argue that the spin effective lattice being identical to the original lattice is a necessary condition for the occurrence of ground-state long-range antiferromagnetic order in the limit Na2→∞. Consistently, strong evidence is provided that for very small hole concentration 0<x1 the ground state has a short-range incommensurate-spiral spin order. Our results are of interest both for condensed-matter systems and ultra-cold fermionic atoms on an optical square lattice.