The Valence Transition Model of Pseudogap, Charge-Order and Superconductivity in Electron- and Hole-Doped Copper Oxides

Abstract

We present a valence transition model for electron- and hole-doped cuprates, within which there occurs a discrete jump in ionicity Cu2+ Cu1+ upon doping, at or near optimal doping in the electron-doped compounds and at the pseudogap phase transition in the hole-doped materials. Doped cuprates have negative charge-transfer gaps, just as rare earth nickelates and BaBiO3. Because of strong correlations and small d-p electron hoppings the systems behave as effective 12-filled Cu-band in the undoped state, and as correlated two-dimensional geometrically frustrated nearly 14-filled O-band in the doped state. The theory gives the simplest yet most comprehensive understanding of experiments in the normal states. The robust antiferromagnetism in the conventional T crystals, the strong role of oxygen deficiency in driving superconductivity and charge carrier sign corresponding to holes at optimal doping are all manifestations of the same quantum state. In the hole-doped pseudogapped state, a biaxial commensurate period 4 charge density wave state of O1--Cu1+-O1- spin-singlets coexists with broken rotational C4 symmetry. Finite domains of this broken symmetry state will exhibit the polar Kerr effect. Superconductivity within the model results from a destabilization of the 14-filled band paired Wigner crystal [Phys. Rev. B 93, 165110 and 93, 205111]. We posit that a similar valence transition, Ir4+ Ir3+, occurs in electron-doped SrIr2O4. We make testable theoretical predictions on cuprates and iridates. Finally, we note that there exist an unusually large number of unconventional superconductors that exhibit superconductivity proximate to exotic charge ordered states, whose bandfillings are also 14, exactly where the paired Wigner crystal is most stable.