d-wave superconductivity in the virtual-electron pair quantum liquid

Abstract

We find evidence that for zero spin density m=0, intermediate U/4t values, and a range x∈ (xc,x*) of finite hole concentrations the ground state of the virtual-electron pair quantum liquid obtained from perturbing the square-lattice quantum liquid of Ref. companion2 by weak three-dimensional (3D) uniaxial anisotropy and intrinsic disorder has long-range d-wave superconducting order. Here t is the effective nearest-neighbor transfer integral and U the effective on-site repulsion. The long-range d-wave superconducting order emerges below a critical temperature Tc for a hole concentration range centered at xop= (xc+x*)/2. It results from the effects of the residual interactions of the charge c fermions and spin-neutral two-spinon s1 fermions of Ref. companion2, as a by-product of the short-range spin correlations. Rather than the U(1) symmetry contained in the η-spin SU(2) symmetry of the SO(4) = [SU(2)× SU(2)]/Z2 symmetry, the U(1) symmetry broken at Tc is the c fermion U(1) symmetry of Ref. bipartite. It is contained in the extended global SO(3)× SO(3)× U(1)=[SO(4)× U(1)]/Z2 symmetry of the Hubbard model on the square lattice. Our preliminary results seem to indicate that combining the electronic correlations described by the square-lattice quantum liquid perturbed by 3D uniaxial anisotropy with the very weak effects of intrinsic disorder or superfluid-density anisotropy leads for the hole-concentration range x∈ (xc,x*) to a successful description of the universal properties of the hole-doped cuprate superconductors.