Title :
High-speed enhancement-mode InP MISFET´s grown by chloride vapor-phase epitaxy
Author :
Antreasyan, Arsam ; Garbinski, P.A. ; Mattera, Vincent D., Jr. ; Feuer, M.D. ; Temkin, H. ; Filipe, J.
Author_Institution :
AT&T Bell Lab., Murray Hill, NJ, USA
fDate :
2/1/1989 12:00:00 AM
Abstract :
The properties of enhancement-mode InP metal-insulator-semiconductor field-effect transistors fabricated on semi-insulating InP substrates are reported. The epitaxial layers of the device structure have been grown by chloride vapor-phase epitaxy. Short-circuit current gain cutoff frequencies of 29.6 GHz were measured for 1-μm-gate-length devices. For devices with submicrometer gate lengths, extrinsic transconductance values up to 300 mS/mm and short-circuit current-gain cutoff frequencies of 38.1 GHz were measured. SiO2 deposited by electron beam evaporation and plasma-enhanced CVD Si3N4 have been utilized as gate insulators, and a drain current drift of 30% within the first 50 h of operation has been observed. The high-speed performance of these devices represent to the authors´ knowledge the fastest InP-based MIS field-effect transistor demonstrated
Keywords :
III-V semiconductors; indium compounds; insulated gate field effect transistors; insulating thin films; semiconductor technology; silicon compounds; solid-state microwave devices; vapour phase epitaxial growth; 1 micron; 29.6 to 38.1 GHz; 300 mS/mm; 50 h; Cl carrier gas; InP MISFET; InP transistors; PECVD; characteristics; cutoff frequencies; drain current drift; electron beam evaporation; enhancement-mode; extrinsic transconductance; gate insulators; high-speed performance; plasma-enhanced CVD; semiconductors; submicrometer gate lengths; Current measurement; Cutoff frequency; Epitaxial growth; Epitaxial layers; FETs; Frequency measurement; Indium phosphide; Metal-insulator structures; Plasma measurements; Substrates;
Journal_Title :
Electron Devices, IEEE Transactions on
