Using fluorescent microthermal imaging we have investigated the origin of 'two-step' behavior in I -V curves for a current-carrying YBa2Cu3Ox superconducting bridge. High resolution temperature maps reveal that as the applied current increases the first step in the voltage corresponds to local dissipation (hot spot), whereas the second step is associated with the onset of global dissipation throughout the entire bridge. A quantitative explanation of the experimental results is provided by a simple model for an inhomogeneous superconductor, assuming that the hot spot nucleates at a location with slightly depressed superconducting properties.
Two-stage dissipation in a superconducting microbridge: experiment and modeling
B A Davidson;E Sarnelli
2010
Abstract
Using fluorescent microthermal imaging we have investigated the origin of 'two-step' behavior in I -V curves for a current-carrying YBa2Cu3Ox superconducting bridge. High resolution temperature maps reveal that as the applied current increases the first step in the voltage corresponds to local dissipation (hot spot), whereas the second step is associated with the onset of global dissipation throughout the entire bridge. A quantitative explanation of the experimental results is provided by a simple model for an inhomogeneous superconductor, assuming that the hot spot nucleates at a location with slightly depressed superconducting properties.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
