Title :
Analysis of NbN Hot Electron Bolometer Receiver Noise Temperatures Above 2 THz With a Quantum Noise Model
Author :
Khosropanah, Pourya ; Zhang, Wen ; Kollberg, Erik L. ; Yngvesson, K. Sigfrig ; Gao, J.R. ; Bansal, Tarun ; Hajenius, Merlijn
Author_Institution :
SRON Netherlands Inst. for Space Res., Groningen, Netherlands
fDate :
6/1/2009 12:00:00 AM
Abstract :
This paper summarizes our receiver noise temperature data of NbN HEB mixers obtained at a number of local oscillator frequencies between 1.9 to 4.3 THz in order to verify the role of quantum noise. The experimental data show that the receiver noise temperature increases roughly linearly with frequency. At 4.3 THz, we measured a receiver noise temperature of 1300 K, which is about 6 times (hf/k B) . The noise data at different frequencies are compared to a prediction of a noise model including the contribution of quantum noise and making use of a hot-spot model for mixing. We draw a preliminary conclusion that at 4.3 THz roughly 30% of the receiver noise temperature can be ascribed to the quantum noise. However, more dedicated measurements are required in order to further support the quantum noise model for HEB mixers.
Keywords :
bolometers; hot carriers; niobium compounds; quantum noise; submillimetre wave mixers; submillimetre wave receivers; superconducting mixers; HEB mixer; NbN; frequency 1.9 THz to 4.3 THz; hot electron bolometer receiver noise temperature; local oscillator frequencies; noise model; quantum noise model; superconducting hot electron bolometer mixer; temperature 1300 K; Heterodyne receiver; THz mixer; quantum noise; superconducting hot electron bolometer mixer; terahertz;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2009.2018817
