Title :
Hot electron effect in the DC SQUID
Author :
Wellstood, F.C. ; Urbina, C. ; Clarke, J.
Author_Institution :
Dept. of Phys., California Univ., Berkeley, CA, USA
fDate :
3/1/1989 12:00:00 AM
Abstract :
The authors investigated the temperature dependence of the noise in thin-film DC superconducting quantum interference devices (SQUIDS) down to 20 mK. The white noise measured in the early versions of the SQUIDS did not decrease as the bath temperature was lowered below 150 mK. The authors have attributed this saturation to a hot electron effect in the thin-film AuCu resistors shunting the Josephson junctions. A theoretical investigation showed that the temperature of the electrons in the shunts should be given by Te=(P/ΣΩ)1/5, where P is the power dissipated in the shunts, Ω is the shunt volume, and Σ is a proportionality constant. Experimentally, the authors found ε=(2.4±0.6)×109 WK-5 m-3. The shunts were redesigned, adding large thin-film cooling fins, to increase their volume substantially. This technique has reduced Te to about 50 mK, with a corresponding improvement in the sensitivity of the SQUIDS
Keywords :
Josephson effect; SQUIDs; electron device noise; hot carriers; AuCu resistors; Josephson junctions; SQUIDS; hot electron effect; large thin-film cooling fins; noise; sensitivity; shunt volume; shunts; temperature dependence; thin-film DC superconducting quantum interference devices; white noise; Electrons; Interference; Noise measurement; SQUIDs; Superconducting device noise; Superconducting devices; Superconducting thin films; Temperature dependence; Thin film devices; White noise;
Journal_Title :
Magnetics, IEEE Transactions on
