A description of the Hubbard model on a square lattice consistent with its global SO(3)× SO(3)× U(1) symmetry

Abstract

In this paper a description of the Hubbard model on the square lattice with nearest-neighbor transfer integral t, on-site repulsion U, and Na2 1 sites consistent with its exact global SO(3)× SO(3)× U(1) symmetry is constructed. Our studies profit from the interplay of that recently found global symmetry of the model on any bipartite lattice with the transformation laws under a suitable electron - rotated-electron unitary transformation of a well-defined set of operators and quantum objects. For U/4t>0 the occupancy configurations of these objects generate the energy eigenstates that span the one- and two-electron subspace. Such a subspace as defined in this paper contains nearly the whole spectral weight of the excitations generated by application onto the zero-spin-density ground state of one- and two-electron operators. Our description involves three basic objects: charge c fermions, spin-1/2 spinons, and η-spin-1/2 η-spinons. Alike in chromodynamics the quarks have color but all quark-composite physical particles are color-neutral, the η-spinon (and spinons) that are not invariant under that transformation have η spin 1/2 (and spin 1/2) but are part of η-spin-neutral (and spin-neutral) 2-η-spinon (and 2-spinon) composite η fermions (and s fermions) where =1,2,... is the number of η-spinon (and spinon) pairs.The description introduced here is consistent with a Mott-Hubbard insulating ground state with antiferromagnetic long-range order for half filling at x=0 hole concentration and a ground state with short-range spin order for a well-defined range of finite hole concentrations x>0.