Physics of short-gate GaAs MESFET's from hydrostatic pressure studies
Abstract
The use of hydrostatic pressure to study the physics of a GaAs MESFET is reported for the first time. Two aspects of the physics of conventional 1-micron gate structures are focused upon: (1) the possible role played by hot-electron effects in the drain-current saturation and (2) the physical mechanism responsible for the excess current. The pressure dependence of the low-field conductance, current-voltage characteristics, and VHF noise properties of the MESFET are examined and compared to those of a Gunn diode. The results show that hot-electron effects are similar in the two devices, thereby providing new evidence that current saturation is associated with Gunn domain formation. The results also suggest that the excess current at large gate voltages is due to electron injection into the substrate under the source side of the gate, rather than to other proposed mechanisms.
- Publication:
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IEEE Transactions on Electron Devices
- Pub Date:
- August 1981
- DOI:
- Bibcode:
- 1981ITED...28..977K
- Keywords:
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- Field Effect Transistors;
- Gallium Arsenides;
- Hydrostatic Pressure;
- Pressure Effects;
- Schottky Diodes;
- Volt-Ampere Characteristics;
- Carrier Injection;
- Gunn Diodes;
- Hot Electrons;
- Metal Surfaces;
- Noise Spectra;
- Power Conditioning;
- Saturation;
- Electronics and Electrical Engineering