Stripes in oxygen-enriched cuprates

Abstract

Charge-order stripes of different types occur when copper oxides are doped with either heterovalent metal, like La2-xSrxCuO4, or oxygen, like YBa2Cu3O6+y. The difference shows up in the doping dependence of their incommensurability: qc(x) x-p but qc(y) ≈ 0.3. The square-root dependence in the former compound family results from Coulomb repulsion between doped holes (or electrons), residing pairwise in lattice-site O (or Cu) atoms of the CuO2 planes. The almost constant qc(y) value in the second family results from the aggregation of ozone-like molecules, formed from O2- ions of the host with embedded oxygen atoms, Oi, at interstitial sites in the CuO2 planes. The magnetic moments, m(O), of the lattice-defect O atoms in the first family arrange antiferromagnetically, which gives rise to accompanying magnetization stripes of incommensurability qm(x) = qc(x)/2. The ozone complexes have a vanishing magnetic moment, m=0, which explains the absence of accompanying magnetization stripes in the second family. Embedding excess oxygen as Oi atoms in CuO2 planes is likewise assumed for HgBa2CuO4+δ and oxygen-enriched bismuth cuprates. A combination of characteristics from both families is present in oxygen-enriched La2CuO4+y. The validity of determining the hole density in oxygen-enriched cuprates with the universal-dome method is independently confirmed. Besides causing different types of stripes, the two types of lattice-defect oxygen may also cause different types of superconductivity. This could explain the much higher Tc,max in oxygen-enriched than Sr-doped cuprates, as well as the cusped cooling-curves of X-ray intensity diffracted by stripes in the former family.