Litcius/Paper detail

Ultrafast Switching of SiC MOSFETs for High-Voltage Pulsed-Power Circuits

M. Azizi, J. J. van Oorschot, T. Huiskamp

2020IEEE Transactions on Plasma Science40 citationsDOI

Abstract

Due to their fast switching capabilities, silicon carbide (SiC) MOSFETs are increasingly used in high-voltage pulsed-power circuits where fast and flexible high-voltage pulses are required (e.g. for plasma-processing applications), such as in our solid-state Impedance-matched Marx generator. The turn-on time of SiC MOSFETs mainly depends on the gate-driving technique and its implementation. Therefore, many studies focus on SiC MOSFET gate-driving methods. In this article, a gate-boosting driving method that was previously proposed for IGBTs is optimized for SiC MOSFETs and applied to a very fast MOSFET to reduce turn-on time as much as possible. A prototype of the optimized gate-boosting driver was built and tested to assess its performance. The test results validate the effectiveness of the optimized gate-driving method and showed that a MOSFET turn-on time of below 2 ns is achievable at a high operating voltage and moderate current and below 3 ns for a wider range of load-current and operating-voltage conditions. Furthermore, current rise rates of 38.7 kA/μs at 356-A load current are possible. All these results are considerably faster than ever demonstrated before.

Topics & Concepts

MOSFETGate driverMaterials scienceSilicon carbidePower MOSFETPulsed powerVoltageSwitching timeElectronic circuitHigh voltageElectrical engineeringLogic gatePower semiconductor deviceOptoelectronicsTransistorEngineeringMetallurgyPulsed Power Technology ApplicationsElectrostatic Discharge in ElectronicsSilicon Carbide Semiconductor Technologies