Title :
Submicrometer n+-Ge gate AlGaAs/GaAs MISFETs
Author :
Hirano, Makoto ; Fujita, Shuichi ; Maezawa, Koichi ; Mizutani, Takashi
Author_Institution :
NTT LSI Lab., Kanagawa, Japan
fDate :
10/1/1989 12:00:00 AM
Abstract :
Submicrometer n+-Ge gate AlGaAs/GaAs MISFETs have been developed by designing a fabrication process for the n+-implanted region. The short-channel effect was sufficiently suppressed by lowering the ion-implantation energy down to 50 keV to achieve a standard deviation of threshold voltage as small as 13 mV for 0.5-μm-gate FETs in a 2-in-diameter wafer. The source resistance was reduced by increasing the annealing temperature to 850°C to obtain a transconductance of 500 mS/mm for a 0.5-μm-gate FET. Even after annealing at such a high temperature, the quality of the channel layer was maintained at a sufficient level to realize a large cutoff frequency of 70 GHz for a 0.4-μm-gate FET. A divide-by-four static frequency divider was also fabricated using the above-mentioned fabrication technology. Successful operation at 16 GHz at 300 K was obtained with a divider using 0.9-μm-gate FETs at a low power dissipation of 36 mW per T-flip-flop
Keywords :
III-V semiconductors; aluminium compounds; field effect integrated circuits; frequency dividers; gallium arsenide; insulated gate field effect transistors; ion implantation; 0.4 micron; 0.5 micron; 0.9 micron; 16 GHz; 300 K; 36 mW; 50 keV; 500 mS; 70 GHz; 850 degC; AlGaAs-GaAs; Ge; MISFETs; annealing temperature; channel layer quality; cutoff frequency; divide-by-four static frequency divider; fabrication process; ion-implantation energy; n+-implanted region; power dissipation; short-channel effect; source resistance; submicrometre n+-Ge gate; threshold voltage; transconductance; Annealing; Cutoff frequency; FETs; Fabrication; Gallium arsenide; MISFETs; Process design; Temperature; Threshold voltage; Transconductance;
Journal_Title :
Electron Devices, IEEE Transactions on
