Abstract
Anomalous resistive peaks below the superconducting transition temperature in heavily boron doped nanocrystalline diamond films could have potential application in switching devices, however it’s exact origin is still under study. We establish a temperature dependence of this resistive phase similar to what has been reported for in Josephson junction arrays and other granular superconductors where the charge duel of the Berezinskii-Kosterlitz-Thouless (BKT) transition has been observed. Non-linear magnetic field dependence of the resistance with a temperature dependent peak feature below the critical field are also presented. Pronounced temperature dependent hysteresis in the current voltage sweeps at temperatures below the determined BKT critical point are related to pinning of charge defects. It is shown that these collective features allude to a Charge-BKT transition between charge and anti-charge analogues.
Highlights
Superconducting Josephson Junction arrays have long been known to exhibit several interesting phenomena important for technological application
Previous results14 have shown the current voltage (I-V) characteristics scale according to a power law indicative of a BKT transition, following convention to further demonstrate the transition here the resistive upturns have been fitted to the square-root-cusp relationship
The dependence on the peak height with applied current is related to the screening length of such charge solitons and explains why the peak is only observed under very specific measurement conditions
Summary
Superconducting Josephson Junction arrays have long been known to exhibit several interesting phenomena important for technological application. Charging effects and anomalous resistive features of superconducting boron doped diamond films
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