Title :
Optimized InP HEMTs for low noise at cryogenic temperatures
Author :
Rodilla, Helena ; Schleeh, Joel ; Nilsson, Per-Ake ; Grahn, Jan
Author_Institution :
Dept. of Microtechnol. & Nanosci. (MC2), Chalmers Univ. of Technol., Göteborg, Sweden
Abstract :
Experimental results and Monte Carlo simulations have been analyzed and compared at 300 K and 77 K for 130 nm gate-length InP HEMTs optimized for cryogenic 4-8 GHz low-noise amplifiers. The good agreement observed between simulations and experimental data for DC and small signal equivalent circuit parameters validates the simulation model. Compared to 300 K, an increase of 17% in the simulated mean electron velocity under the gate was observed at low drain current (100 mA/mm) when operating the device at 77 K. In addition, a better electron confinement in the channel was noted. The observations are consistent with an increase of the slope of the transconductance versus gate bias with reduced temperature. The high transconductance at low drain current is crucial for low noise operation of the InP HEMT at low temperature.
Keywords :
Monte Carlo methods; cryogenics; equivalent circuits; high electron mobility transistors; indium compounds; low noise amplifiers; optimisation; DC equivalent circuit; InP; Monte Carlo simulations; channel electron confinement; cryogenic low noise amplifiers; cryogenic temperatures; drain current; frequency 4 GHz to 8 GHz; gate bias; optimized InP HEMT; simulated mean electron velocity; size 130 nm; small signal equivalent circuit; temperature 300 K; temperature 77 K; transconductance slope; Cryogenics; HEMTs; Indium phosphide; Logic gates; MODFETs; Monte Carlo methods; Noise; Cryogenic temperatures; InP high electron mobility transistors; Monte Carlo simulations; low noise;
Conference_Titel :
Indium Phosphide and Related Materials (IPRM), 2012 International Conference on
Conference_Location :
Santa Barbara, CA
Print_ISBN :
978-1-4673-1725-2
DOI :
10.1109/ICIPRM.2012.6403368
