c-axis charge gap and its critical point in the heavily doped Ba(Fe1-xCox)2As2

Abstract

Temperature-dependent inter-plane resistivity, c(T), was used to characterise the normal state of the iron-arsenide superconductor Ba(Fe1-xCox)2As2 over a broad doping range 0≤ x<0.50. The data were compared with in-plane resistivity, a(T), and magnetic susceptibility, (T), taken in H c, as well as Co NMR Knight shift, 59K, and spin relaxation rate, 1/T1T. The inter-plane resistivity data show a clear correlation with the NMR Knight shift, assigned to the formation of the pseudo-gap. Evolution of c(T) with doping reveals two characteristic energy scales. The temperature of the cross-over from non-metallic, increasing on cooling, behavior of c(T) at high-temperatures to metallic behavior at low temperatures, T*, correlates well with an anomaly in all three magnetic measurements. This characteristic temperature, equal to approximately 200~K in the parent compound, x=0, decreases with doping and vanishes near x* ≈0.25. For doping levels x ≥ 0.166, an additional feature appears above T*, with metallic behavior of c (T) found above the low-temperature resistivity increase. The characteristic temperature of this charge-gap formation, T CG, vanishes at x CG 0.30, paving the way to metallic, T-linear, c (T) close to x CG and super-linear T-dependence for x>x CG. None of these features are evident in the in-plane resistivity a(T). For doping levels x <x CG, (T) shows a known, anomalous, T-linear dependence, which disappears for x>x CG.