Title :
A 50 nm gate length InN tri-gate FET design with gm of 1.07 mS/μm and ft of 495 GHz
Author :
Ghosh, Koushik ; Singisetti, Uttam
Author_Institution :
Dept. of Electr. Eng., SUNY - Univ. at Buffalo, Buffalo, NY, USA
Abstract :
Among III-N semiconductors, InN has long been attractive for high-frequency devices because of its predicted high electron velocity (> 3 × 107 cm/s) and low effective mass [1]. However, experimental devices have been hard to demonstrate due to high n-type unintentional doping densities (UID) (> 1017 cm-3) and large surface conduction. In this work, through comprehensive simulation, we show that through judicious design of a tri-gate InN device and polarization engineering, a FET operation is realized even with high UID. The simulated 50 nm gate length device shows excellent DC and RF performance with calculated values of gm 1.07 mS/μm, ft 495 GHz, intrinsic fmax 760 GHz, and off state current of 0.007 mA/ μm.
Keywords :
III-V semiconductors; field effect transistors; indium compounds; millimetre wave field effect transistors; DC performance; FET operation; III-N semiconductors; InN; RF performance; comprehensive simulation; frequency 495 GHz; frequency 760 GHz; gate length; high electron velocity; low effective mass; off state current; polarization engineering; size 50 nm; tri-gate FET design; Doping; Educational institutions; Field effect transistors; Logic gates; Mathematical model; Radio frequency; Semiconductor process modeling;
Conference_Titel :
Device Research Conference (DRC), 2013 71st Annual
Conference_Location :
Notre Dame, IN
Print_ISBN :
978-1-4799-0811-0
DOI :
10.1109/DRC.2013.6633803
