Title :
Diffusion-cooled superconducting hot electron bolometer heterodyne mixer between 630 and 820 GHz
Author :
Fiegle, K. ; Diehl, D. ; Jacobs, K.
Author_Institution :
I. Phys. Inst., Koln Univ., Germany
fDate :
6/1/1997 12:00:00 AM
Abstract :
We report on heterodyne mixing experiments between 630-820 GHz using a diffusion-cooled superconducting hot electron bolometer at intermediate frequencies from 1-2 GHz. The niobium bolometer which is cooled by diffusion of the hot electrons into a normal conductor has dimensions of 0.3 /spl mu/m/spl times/0.15 /spl mu/m and was fabricated at KOSMA with a two-step electron beam lithography process. The film thickness of the device is 30 nm with T/sub c/ of 6.1 K and /spl Delta/T/sub c/ of 0.7 K. The mixing experiments are performed with a tunerless waveguide mixer block previously used for very low-noise SIS receivers. At a physical temperature of 2.2 K, receiver noise temperatures at 666 GHz are 1500 K at 1.0 GHz intermediate frequency, increasing rapidly above 1.5 GHz. The dissipated local oscillator power is evaluated to be 65-90 nW.
Keywords :
bolometers; electron beam lithography; hot carriers; niobium; submillimetre wave mixers; submillimetre wave receivers; superconducting device noise; superconducting device testing; superconducting microbridges; superconducting microwave devices; superconducting thin films; 1 to 2 GHz; 2.2 K; 30 nm; 6.1 K; 630 to 820 GHz; 65 to 90 nW; Nb; Nb bolometer; diffusion-cooled superconducting hot electron bolometer; dissipated local oscillator power; film thickness; heterodyne mixing experiments; intermediate frequencies; receiver noise temperatures; tunerless waveguide mixer block; two-step electron beam lithography process; Bolometers; Conductors; Electron beams; Frequency; Lithography; Niobium; Superconducting devices; Superconducting films; Temperature; Tuners;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
