Title :
Design and performance of 0.1- mu m CMOS devices using low-impurity-channel transistors (LICT´s)
Author :
Aoki, Masaaki ; Ishii, Tatsuya ; Yoshimura, Toshiyuki ; Kiyota, Yukihiro ; Iijima, Shimpei ; Yamanaka, Toshiaki ; Kure, Tokuo ; Ohyu, Kiyonori ; Nishida, Takashi ; Okazaki, Shinji ; Seki, Kohichi ; Shimohigashi, Katsuhiro
Author_Institution :
Hitachi Ltd., Tokyo, Japan
Abstract :
0.1- mu m CMOS devices using low-impurity-channel transistors (LICTs) with dual-polysilicon gates have been fabricated by nondoped epitaxial growth technology, high-pressure oxidation of field oxide, and electron-beam lithography. These devices, with gate lengths of 0.135 mu m, achieved normal transistor operation at both 300 and 77 K using 1.5-V supply voltage. Maximum transconductances are 203 mS/mm for nMOS transistors and 124 mS/mm for pMOS transistors at 300 K. Low-impurity channels grown on highly doped wells provide low threshold voltages of about 0.35 V for nMOS transistors and about -0.15 V for pMOS transistors at 77 K, and preserve good turn-offs with subthreshold swings of 25 mV/decade at 77 K. LICTs suppress short-channel effects more effectively, compared with conventional devices with nearly uniform dopings.<>
Keywords :
CMOS integrated circuits; electron beam lithography; insulated gate field effect transistors; oxidation; semiconductor epitaxial layers; vapour phase epitaxial growth; 0.1 micron; 1.5 V; 300 K; 77 K; electron-beam lithography; fabrication; highly doped wells; low voltage operation; low-impurity-channel transistors; nondoped epitaxial growth; performance; short-channel effects suppression; supply voltage; threshold voltages; transconductances; transistor operation; CMOS technology; Epitaxial growth; MOS devices; MOSFETs; Oxidation; Rough surfaces; Substrates; Surface roughness; Threshold voltage; Very large scale integration;
Journal_Title :
Electron Device Letters, IEEE
