Litcius/Paper detail

Novel Drain-Connected Field Plate GaN HEMT Designs for Improved <i>V</i> <sub>BD</sub>–<i>R</i> <sub>ON</sub> Tradeoff and RF PA Performance

Ankit Soni, Ajay, Mayank Shrivastava

2020IEEE Transactions on Electron Devices70 citationsDOI

Abstract

TCAD studies are performed to develop physical insights into the breakdown behavior of drain-connected field plate-based GaN HEMTs. Using the developed insights, to mitigate the performance bottleneck caused by the lateral drain-connected field plate design, we have proposed novel vertical-field-plate designs. The proposed designs alleviate the channel electric field by uniformly distributing it vertically into the GaN buffer region. As a result, the proposed vertical and dual-field-plate design offer 2× and 3× improvements in breakdown voltage, respectively, compared with the design without field plate. Similarly, compared with a design with a lateral field plate, a 50% improvement in the breakdown voltage was seen with dual-field-plate architecture. RF power amplifier (PA) performance extracted using load-pull simulations demonstrates an improved RF PA linearity at higher drain bias, improved output power, efficiency, and PA gain for HEMTs with dual- and vertical-field-plate designs.

Topics & Concepts

High-electron-mobility transistorBreakdown voltageAmplifierElectric fieldField (mathematics)Electrical engineeringMaterials scienceVoltageOptoelectronicsLinearityEngineeringElectronic engineeringTransistorPhysicsMathematicsPure mathematicsCMOSQuantum mechanicsGaN-based semiconductor devices and materialsRadio Frequency Integrated Circuit DesignSilicon Carbide Semiconductor Technologies