Multilayered cuprate superconductor Ba2Ca5Cu6O12(O1-x,Fx)2 studied by temperature-dependent scanning tunneling microscopy and spectroscopy

Abstract

Scanning tunneling microscopy/spectroscopy (STM/STS) measurements were carried out on a multi-layered cuprate superconductor Ba2Ca5Cu6O12(O1-x,Fx)2. STM topography revealed random spot structures with the characteristic length 0.5 nm. The conductance spectra dI/dV(V) show the coexistence of smaller gaps S and large gaps (pseudogaps) L. The pseudogap-related features in the superconducting state were traced with the spatial resolution of 0.07 nm. Here, I and V are the tunnel current and bias voltage, respectively. The temperature, T, dependence of S follows the reduced Bardeen-Cooper-Schrieffer (BCS) dependence. The hallmark ratio 2S(T=0)/kB Tc equals to 4.9, which is smaller than those of other cuprate superconductors. Here, Tc is the superconducting critical temperature and kB is the Boltzmann constant. The larger gap L survives in the normal state and even increases with T above Tc. The T dependences of the spatial distributions for both relevant gaps ( map), as well as for each gap separately (S and L) were obtained. From the histogram of map, the averaged gap values were found to be S = 24 meV and L = 79 meV. The smaller gap S shows a spatially homogeneous distribution while the larger gap L is quite inhomogeneous, indicating that rather homogeneous superconductivity coexists with the patchy distributed pseudogap. The spatial variation length _L of L correlates with the scale of the topography spot structures, being approximately 0.4 nm. This value is considerably smaller than the coherence length of this class of superconductors, suggesting that L is strongly affected by the disorder of the apical O/F.