Title :
Modeling the Behavior of HTS Terahertz RSQUIDs
Author :
Pegrum, Colin M. ; Macfarlane, John C. ; Du, Jia
Author_Institution :
FieldSolutions, Glasgow, UK
fDate :
6/1/2011 12:00:00 AM
Abstract :
In previous work we looked in detail at simulations of our HTS Resistive DC SQUIDs (RSQUIDs) using a lumped-component model and neglecting step-edge junction capacitance. These can now be made with junctions that have a high product of critical current and normal resistance (IcRJ) and so the Josephson frequency can be above 1 THz. This calls for a more refined model of the device, which we will present here. The RSQUID series resistor is represented as a distributed combination of resistance and inductance, rather than simply a resistor in series with its self inductance. We now include junction capacitance, as the Stewart-McCumber parameter can be close to unity. We treat the RSQUID loop as a co-planar stripline, rather than as an inductor. We report a range of simulations with these enhancements to the model and comment briefly on the results in relation to potential applications of RSQUIDs as active microwave devices.
Keywords :
SQUIDs; superconducting microwave devices; HTS resistive DC SQUIDs; HTS terahertz RSQUIDs; Josephson frequency; RSQUID loop; RSQUID series resistor; Stewart-McCumber parameter; active microwave devices; coplanar stripline; critical current; lumped-component model; normal resistance; step-edge junction capacitance; Capacitance; Gold; Inductance; Integrated circuit modeling; Junctions; Resistors; SQUIDs; Heterodyning; Josephson mixers; Josephson oscillators; SQUIDs; superconducting microwave devices;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2010.2091094
