Title :
High-Performance 90-nm Dual-Gate nMOSFETs With Field-Plate Technology
Author :
Fu, Jeffrey S. ; Chiu, Hsien-Chin ; Ke, Po-Yu ; Chen, Ting-Huei ; Feng, Wu-Shiung
Author_Institution :
Dept. of Electron. Eng., Chang Gung Univ., Taoyuan, Taiwan
fDate :
3/1/2011 12:00:00 AM
Abstract :
In this letter, high-performance 90-nm dual-gate nMOSFETs with field-plate (FP) metal were demonstrated for high-power and low-frequency noise device applications. The pro posed dual-gate nMOSFETs with FP metals had a higher maximum oscillation frequency (fMAX)>; a lower noise power spectral density, and a higher output power (Pout) than traditional dual gate architecture. These improvements were obtained because two extra FP-induced depletion regions were present, and the total electrical field was suppressed, yielding high output resistance and higher output power. These FP-induced depletion regions also pushed the carriers into deeper channels and reduced the number of opportunities for carriers to be trapped by surface states between gate and drain terminals. Based on the dependence of the normalized noise power spectral density (SID/ID2) on the gate voltage, the FP dual gate had a low noise power spectral density and a low range of Hooge factors at high current.
Keywords :
MOSFET; FP metal; FP-induced depletion regions; Hooge factors; dual gate architecture; dual-gate nMOSFET; electrical field; field-plate technology; low-frequency noise device; maximum oscillation frequency; noise power spectral density; size 90 nm; Logic gates; Low-frequency noise; MOSFETs; Metals; Power generation; 90-nm nMOS; $f_{rm MAX}$; Dual gate; field plate (FP); low-frequency noise; power density;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2010.2102738
