Abstract:
We demonstrate that the highly resistive Si substrate in GaN-on-Si RF HEMTs does not act as an insulator, but instead behaves as a conductive ground plane for static oper...Show MoreMetadata
Abstract:
We demonstrate that the highly resistive Si substrate in GaN-on-Si RF HEMTs does not act as an insulator, but instead behaves as a conductive ground plane for static operation and can cause significant back-gate-induced current collapse. Substrate ramp characterization of the buffer shows good agreement with device simulations and indicates that the current collapse is caused by charge-redistribution within the GaN layer. Potential solutions, which alter charge storage and leakage in the epitaxy to counter this effect, are then presented.
Published in: IEEE Electron Device Letters ( Volume: 39, Issue: 10, October 2018)
Funding Agency:
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- IEEE Keywords
- Index Terms
- Si Substrate ,
- GaN HEMT ,
- Current Collapse ,
- Conductive ,
- Epitaxial ,
- Ground Plane ,
- Static Performance ,
- Charge Storage ,
- Device Simulation ,
- GaN Layer ,
- Negatively Charged ,
- Power Devices ,
- Ramp Rate ,
- Channel Conductance ,
- Thermal Power Plants ,
- Charge Trapping ,
- Vertical Field ,
- Drain Current ,
- Epitaxial Layer ,
- Substrate Contact ,
- Si Doping ,
- Drain Bias ,
- Inversion Layer
- Author Keywords
Contents Keywords assist with retrieval of results and provide a means to discovering other relevant content. Learn more.
- IEEE Keywords
- Index Terms
- Si Substrate ,
- GaN HEMT ,
- Current Collapse ,
- Conductive ,
- Epitaxial ,
- Ground Plane ,
- Static Performance ,
- Charge Storage ,
- Device Simulation ,
- GaN Layer ,
- Negatively Charged ,
- Power Devices ,
- Ramp Rate ,
- Channel Conductance ,
- Thermal Power Plants ,
- Charge Trapping ,
- Vertical Field ,
- Drain Current ,
- Epitaxial Layer ,
- Substrate Contact ,
- Si Doping ,
- Drain Bias ,
- Inversion Layer
- Author Keywords