Reduction of sidegating in GaAs analog and digital circuits using a new buffer layer

Author

Chen, Chang-Lee ; Smith, Frank W. ; Calawa, Arthur R. ; Mahoney, Leonard J. ; Manfra, Michael J.

Author_Institution

MIT, Lexington, MA, USA

Volume

36

Issue

9

fYear

1989

fDate

9/1/1989 12:00:00 AM

Firstpage

1546

Lastpage

1556

Abstract

Sidegating effects relevant to GaAs digital, analog, and monolithic microwave integrated circuits have been significantly reduced or eliminated by using a low-temperature buffer layer grown by molecular-beam epitaxy. At radio frequencies the low-temperature buffer layer reduced the signal coupling between devices, which is an important consideration in microwave integrated circuits. For digital circuit applications, the low-temperature buffer layer eliminated the dependence of the voltage level of an inverter on the logic state of adjacent devices and on the duty cycle of a pulse train encountered in the circuit. The highly resistive nature of the low-temperature buffer allows experimental identification of the role that a buffer layer plays in sidegating

Keywords

III-V semiconductors; MMIC; Schottky gate field effect transistors; digital integrated circuits; field effect integrated circuits; gallium arsenide; integrated circuit technology; linear integrated circuits; semiconductor device models; semiconductor technology; GaAs; MESFET IC; analog circuits; digital circuits; low-temperature buffer layer; molecular-beam epitaxy; monolithic microwave integrated circuits; radio frequencies; sidegating reduction; Analog integrated circuits; Buffer layers; Digital circuits; Digital integrated circuits; Gallium arsenide; MMICs; Microwave devices; Microwave integrated circuits; Monolithic integrated circuits; Pulse inverters;

fLanguage

English

Journal_Title

Electron Devices, IEEE Transactions on

Publisher

ieee

ISSN

0018-9383

Type

jour

DOI

10.1109/16.34211

Filename

34211