Uniform mixing of antiferromagnetism and high-Tc superconductivity in multilayered copper oxides Ba2Can-1CunO2nF2 with apical fluorines (n=2,3,4): Cu-NMR/NQR and F-NMR

Abstract

We report Cu-NMR/NQR and F-NMR studies on the multilayered high-Tc copper oxides Ba2Can-1CunO2nF2 with n=2,3,4, where n is the number of CuO2 planes. It is revealed that bi-layered Ba2CaCu2O4F2 is an underdoped superconductor with hole carriers, which are introduced into CuO2 planes by an unexpected deviation from the nominal content of apical fluorines. In a previous paper, we proposed a self-doping mechanism as the origin of carrier doping in n=3 and n=4; in the mechanism, electrons are transferred from the inner CuO2 plane (IP) to the outer one (OP). However, since it has been found that the bi-layered compound is hole doped, we have reexamined the superconducting and magnetic properties in n=3 and n=4 by Cu-NMR/NQR and F-NMR. The extensive NMR studies have confirmed that the apical-fluorine compounds are not self-doped but hole-doped, and that antiferromagnetism (AFM) and superconductivity (SC) coexist in a single CuO2 plane. In n=4, the AFM ordering occurs at TN = 80 K, well above Tc=55 K, where the respective AFM moments are MAFM=0.11 muB and 0.18 muB at the OP and the IP. In n=3, on the other hand, the underdoped single IP exhibits a spontaneous moment MAFM=0.12 muB at low temperatures and a peak in the nuclear-spin-lattice relaxation rate 1/T1 of F at TN=23 K, much lower than Tc = 76 K. We note that the increase in the number of IPs from one to two leads to an increase in TN due to strengthening the interlayer coupling, although the doping levels for both compounds are almost comparable. The present results strongly suggest that the uniform mixing of AFM and SC is a general property inherent to a single CuO2 plane in the underdoped regime for hole-doping.