Title :
Millimeter-wave response in NbN(g)/Al nanobridges
Author :
Wang, Z. ; Hamasaki, Kazuki ; Kinoshita, M. ; Yamashita, Takayoshi ; Matsui, T. ; Komiyama, B.
Author_Institution :
Dept. of Electron., Nagaoka Univ. of Technol., Japan
fDate :
3/1/1991 12:00:00 AM
Abstract :
The testing of NbN(g) nanobridges with Al direct shunt resistors for use as millimeter-wave Josephson mixers is discussed. The NbN(g)/Al nanobridges have a nearly sinusoidal current-phase relation, high resistance, well-defined gap structure at ~4 mV, large IJ RN products of ~3 mV, and nonhysteresis I -V curves. By means of the Al direct shunt, the effective noise temperature TNeff of the NbN(g) nanobridges, which was calculated by transition-state theory, was reduced to 4.2 K as a result of reducing the self-heating and noise rounding effects. The NbN(g)/Al nanobridges show almost ideal Josephson response to millimeter-wave radiation at 106 GHz. The well-pronounced Josephson steps were observed up to ~4 mV. The observed systematic decreasing of the step heights with increasing the RF current can be accounted for by the effect of the thermal noise if an effective noise temperature of TN=15 K (at iRF=3) is assumed. The IF peaks in the Josephson mixing were obtained up to the bias voltage of ~1.2 mV. The NEP was about 3×10-20 W/Hz at 4.2 K
Keywords :
mixers (circuits); niobium compounds; solid-state microwave devices; superconducting junction devices; 106 GHz; 4 mV; Al direct shunt resistors; EHF; Josephson response to millimeter-wave radiation; Josephson steps; NbN-Al nanobridges; gap structure; high resistance; millimeter-wave Josephson mixers; noise temperature; sinusoidal current-phase relation; thermal noise; Artificial intelligence; Critical current; Hysteresis; Inductors; Plasma measurements; Plasma temperature; Radio frequency; SQUIDs; Testing; Tuners;
Journal_Title :
Magnetics, IEEE Transactions on
