Planar CuO2 hole density estimation in multilayered high-Tc cuprates

Abstract

We report that planar CuO2 hole densities in high-Tc cuprates are consistently determined by the Cu-NMR Knight shift. In single- and bi-layered cuprates, it is demonstrated that the spin part of the Knight shift Ks(300 K) at room temperature monotonically increases with the hole density p from underdoped to overdoped regions, suggesting that the relationship of Ks(300 K) vs. p is a reliable measure to determine p. The validity of this Ks(300 K)-p relationship is confirmed by the investigation of the p-dependencies of hyperfine magnetic fields and of spin susceptibility for single- and bi-layered cuprates with tetragonal symmetry. Moreover, the analyses are compared with the NMR data on three-layered Ba2Ca2Cu3O6(F,O)2, HgBa2Ca2Cu3O8+delta, and five-layered HgBa2Ca4Cu5O12+delta, which suggests the general applicability of the Ks(300 K)-p relationship to multilayered compounds with more than three CuO2 planes. We remark that the measurement of Ks(300 K) enables us to separately estimate p for each CuO2 plane in multilayered compounds, where doped hole carriers are inequivalent between outer CuO2 planes and inner CuO2 planes.