Title :
High-performance self-aligned p+/n GaAs epitaxial JFET´s incorporating AlGaAs etch-stop layer
Author :
Abrokwah, J.K. ; Leybovich, I.S. ; Szalkowski, F.J. ; Watanabe, S.H.
Author_Institution :
McDonnel Douglas Electron. Syst. Co., Huntington Beach, CA, USA
fDate :
6/1/1990 12:00:00 AM
Abstract :
The fabrication of high-transconductance epitaxial GaAs JFETs using a refractory metal self-aligned gate (SAG) process is discussed. By applying a highly doped, shallow epitaxial channel (n≈1×1018 cm-3), a T-gate structure consisting of WSi or WN/p+ GaAs, and a thin undoped AlGaAs etch-stop layer (75 Å) separating the p+ GaAs and the active JFET n-channel, high-performance devices which show GaAs JFETs to be applicable to ultra-high-speed circuits have been realized. 1-, 0.85-, and 0.6-μm gate length devices of 10-μm gate width and threshold voltages near 0.3 V exhibited transconductances of 354, 406, and 440 mS/mm, respectively, at Vgs=1 V and V ds of 1.5 V. The 0.6×10-μm device exhibited a peak transconductance of 554 mS/mm at Vgs=1.3 V and a K value of 352 μA/V2-μm. The peak transconductance occurs at a gate-to-source voltage below the bipolar regime of conduction of the FETs
Keywords :
III-V semiconductors; gallium arsenide; junction gate field effect transistors; metallisation; semiconductor epitaxial layers; semiconductor-metal boundaries; tungsten compounds; 0.3 V; 1 to 0.6 micron; 10 micron; 75 A; AlGaAs etch-stop layer; AlGaAs-GaAs; JFETs; SAG; T-gate structure consisting; WN-GaAs; WSi-GaAs; fabrication; gate length; gate width; gate-to-source voltage; high-transconductance; refractory metal self-aligned gate; semiconductors; shallow epitaxial channel; silicides; threshold voltages; transconductances; ultra-high-speed circuits; Diffusion processes; Etching; FETs; Fabrication; Gallium arsenide; JFET circuits; MESFET circuits; P-n junctions; Threshold voltage; Transconductance;
Journal_Title :
Electron Devices, IEEE Transactions on
