Normal-state resistivity and the depairing current density of BaFe2(As,P)2 nanobridges along the c axis

Abstract

We report precise measurements to obtain the normal-state resistivity and the depairing current density of BaFe2(As1-xPx)2(x0.29-0.32) nanobridges along the c axis, which are fabricated from single crystals near the optimal doping, by using focused ion beam (FIB) techniques. We obtained both of the ab-plane and c-axis resistivity (ab and c) in the same part of a specimen, by fabricating the c-axis nanobridge in the middle of a narrow bridge extended in ab-plane, in spite of the slight deficiency of P dopant due to the additional FIB fabrication. The normal-state resistivity anisotropy agreed with the previous results for bulk samples, showing c/ab < 8 just above the superconducting transition temperature, Tc, in the slightly underdoped region and a slight decrease with increasing temperatures. The critical current density obtained in the c-axis nanobridges near the optimal doping reaches 8 MA/cm2 at 0.15Tc, corresponding to about 87 % of a depairing limit derived by the Eilenberger equations. An extrapolation to T=0 K using the Ginzburg-Landau model suggests that the anisotropy of the depairing current density roughly corresponds to that of the normal-state resistivity. At low temperatures, we also observed a step-like voltage jump before arriving at the depairing limit, suggesting the occurrence of phase-slip phenomena near the depairing processes.