Title :
Device Design Guidelines for Nanoscale FinFETs in RF/Analog Applications
Author :
Sohn, Chang-Woo ; Kang, Chang Yong ; Baek, Rock-Hyun ; Choi, Do-Young ; Sagong, Hyun Chul ; Jeong, Eui-Young ; Baek, Chang-Ki ; Lee, Jeong-Soo ; Lee, Jack C. ; Jeong, Yoon-Ha
Author_Institution :
Dept. of Electr. Eng., Pohang Univ. of Sci. & Technol., Pohang, South Korea
Abstract :
This letter proposes simple guidelines to design nanoscale fin-based multigate field-effect transistors (FinFETs) for radio frequency (RF)/analog applications in terms of fin height and fin spacing. Geometry-dependent capacitive and resistive parasitics are evaluated using analytic models and are included in a small-signal circuit. It is found that reducing the fin-spacing-to-fin-height ratio of FinFETs, as long as it is compatible with the process integration, is desirable for improving RF performance. This is because the current-gain cutoff frequency and the maximum oscillation frequency are affected by decreasing parasitic capacitance more than by increasing series resistance.
Keywords :
MOSFET; millimetre wave field effect transistors; semiconductor device models; submillimetre wave transistors; RF-analog applications; analytic models; current-gain cutoff frequency; device design guidelines; fin spacing-to-fin height ratio; fin-based multigate field-effect transistors; geometry-dependent capacitive parasitics; geometry-dependent resistive parasitics; nanoscale FinFET; oscillation frequency; process integration; radiofrequency-analog applications; series resistance; small-signal circuit; Capacitance; Cutoff frequency; FinFETs; Logic gates; Nanoscale devices; Radio frequency; Resistance; Analytic model; fin height; fin spacing; fin-based multigate field-effect transistors (FETs) (FinFETs); parasitic capacitance; radio frequency (RF); series resistance;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2012.2204853
