Title :
Device physics and technology of complementary silicon MESFET´s for VLSI applications
Author :
MacWilliams, Kenneth P. ; Plummer, James D.
Author_Institution :
Dept. of Electr. Eng., Stanford Univ., CA, USA
fDate :
12/1/1991 12:00:00 AM
Abstract :
The development of a complete complementary MESFET technology is presented. The state-of-the-art, fully implanted, CMOS-like process uses Shannon implants together with a refractory silicide Schottky-gate material to combine high gate barrier heights with ease of fabrication. To minimize parasitic resistances, a unique sidewall structure and sidewall spacers are utilized to allow for self-aligned implantation of the source/drain regions. A self-aligned titanium silicidation technique is employed to minimize sheet and contact resistance of the source/drain regions. The SUPREM process simulator was employed extensively. The performance and modeling of device parameters (e.g., threshold voltage, gate leakage, and short-channel effects) and circuit parameters (e.g. standby current, noise margin, and speed) were accomplished through analytic formulations, the PISCES two-dimensional device simulator, and the SPICE circuit simulator
Keywords :
Schottky gate field effect transistors; VLSI; field effect integrated circuits; integrated circuit technology; ion implantation; metallisation; PISCES two-dimensional device simulator; SPICE circuit simulator; SUPREM process simulator; Shannon implants; Ti silicidation; TiSi2; VLSI applications; complementary MESFET technology; contact resistance; gate leakage; high gate barrier heights; noise margin; parasitic resistances; refractory silicide Schottky-gate material; self-aligned implantation; sheet resistance; short-channel effects; sidewall spacers; sidewall structure; speed; standby current; threshold voltage; Analytical models; CMOS technology; Circuit simulation; Implants; MESFETs; Physics; Sheet materials; Silicides; Silicon; Space technology;
Journal_Title :
Electron Devices, IEEE Transactions on
