DocumentCode
2993569
Title
High power InAlAs/InGaAs/InP-HFET grown by MOVPE
Author
Daumann, W. ; Scheffer, F. ; Frost, W. ; Tegude, F.J.
Author_Institution
Gerhard-Mercator Univ., Duisburg, Germany
fYear
1997
fDate
11-15 May 1997
Firstpage
24
Lastpage
27
Abstract
In this study we report the impact of an extended lateral gate-recess process in order to reduce the high electric field at the drain end of the gate and so to improve the breakdown performance. At first, we focus on an HFET fabricated by optical lithography (Lg =0.7 μm). The influence of various gate recess procedures on both the breakdown voltage and the drain saturation current is studied for various thickness of the barrier and supply layer, respectively. High power class A amplifiers exhibiting DC (RF) power capabilities in the range of 4-5 W/mm (0.5-0.75 W/mm) are presented. Then, we introduce a hybrid lithography process combining both optical and electron beam lithography. In this way a shorter gate (Lg=0.35 μm) is asymmetrically positioned in an extended lateral gate recess which enables both high breakdown voltage and increased cut off frequency
Keywords
III-V semiconductors; S-parameters; aluminium compounds; electric breakdown; electron beam lithography; gallium arsenide; indium compounds; microwave field effect transistors; microwave power amplifiers; microwave power transistors; millimetre wave amplifiers; millimetre wave field effect transistors; millimetre wave power transistors; photolithography; power amplifiers; power field effect transistors; semiconductor growth; vapour phase epitaxial growth; 0.35 mum; 0.7 mum; 45 MHz to 45 GHz; DC power capabilities; In0.52Al0.48As-In0.53Ga0.47 As-InP; InP:Fe; MOVPE growth; RF power capabilities; S-parameters; barrier layer thickness; breakdown performance; cut off frequency; drain saturation current; electron beam lithography; extended lateral gate-recess process; high electric field; high power class A amplifiers; hybrid lithography process; mm-wave regime; optical lithography; power InAlAs/InGaAs/InP-HFET; supply layer thickness; Electric breakdown; Epitaxial growth; Epitaxial layers; HEMTs; Indium compounds; Indium gallium arsenide; Lithography; MODFETs; Optical saturation; Stimulated emission;
fLanguage
English
Publisher
ieee
Conference_Titel
Indium Phosphide and Related Materials, 1997., International Conference on
Conference_Location
Cape Cod, MA
ISSN
1092-8669
Print_ISBN
0-7803-3898-7
Type
conf
DOI
10.1109/ICIPRM.1997.600019
Filename
600019
Link To Document