In-plane current-voltage characteristics and oscillatory Josephson-vortex flow resistance in La-free Bi2+xSr2-xCuO6+δ single crystals in high magnetic fields

Abstract

We have investigated the in-plane I(V) characteristics and the Josephson vortex flow resistance in high-quality La-free Bi2+xSr2-xCuO6+δ (Bi2201) single crystals in parallel and tilted magnetic fields at temperatures down to 40 mK. For parallel magnetic fields below the resistive upper critical field H*c2, the I(V) characteristic obey a power-law with a smooth change with increasing magnetic-field of the exponent from above 5 down to 1. In contrast to the double-layer cuprate Bi2212, the observed smooth change suggests that there is no change in the mechanism of dissipation (no Kosterlitz-Thouless transition) over the range of temperatures investigated. At small angles between the applied field and the ab-plane, prominent current steps in the I(V) characteristics and periodic oscillations of Josephson-vortex flow resistance are observed. While the current steps are periodic in the voltage at constant fields, the voltage position of the steps, together with the flux-flow voltage, increases nonlinearly with magnetic field. The ab-flow resistance oscillates as a function of field with a constant period over a wide range of magnetic fields and temperatures. The current steps in the I(V) characteristics and the flow resistance oscillations can be linked to the motion of Josephson vortices across layers.