SiC power MOSFETs performance, robustness and technology maturity

Relatively recently, SiC power MOSFETs have transitioned from being a research exercise to becoming an industrial reality. The potential benefits that can be drawn from this technology in the electrical energy conversion domain have been amply discussed and partly demonstrated. Before their widespread use in the field, the transistors need to be thoroughly investigated and later validated for robustness and longer term stability and reliability. This paper proposes a review of commercial SiC power MOSFETs state-of-the-art characteristics and discusses trends and needs for further technology improvements, as well as device design and engineering advancements to meet the increasing demands of power electronics

Gate oxide failure in MOS devices

The thesis presents an experimental and theoretical investigation of gate oxide breakdown in MOS networks, with a particular emphasis on constant voltage overstress failure. It begins with a literature search on gate oxide failure mechanisms, particularly time-dependent dielectric breakdown, in MOS devices. The experimental procedure is then reported for the study of gate oxide breakdown under constant voltage stress. The experiments were carried out on MOSFETs and MOS capacitor structures, recording the characteristics of the devices before and after the stress. The effects of gate oxide breakdown in one of the transistors in an nMOS inverter were investigated and several parameters were found to have changed. A mathematical model for oxide breakdown, based on physical mechanisms, is proposed. Both electron and hole trapping occurred during the constant voltage stress. Breakdown appears to take place when the trapped hole density reach a critical value. PSPICE simulations were performed for the MOSFETs, nMOS inverter and CMOS logic circuits. Two models of MOSFET with gate oxide short were validated. A good agreement between experiments and simulations was achieved

Bias temperature instability and junction temperature measurement using electrical parameters in SiC power MOSFETs

Junction temperature sensing is an integral part of both on-line and off-line condition monitoring where direct access the bare die surface is not available. Given a defined power input, the junction temperature enables the estimation of the junction-to-case thermal resistance, which is a key indicator of packaging failure mechanisms like solder voiding and cracks. The use of temperature sensitive electrical parameters has widely been proposed as a means of junction temperature sensing however, there are certain challenges regarding their use in SiC MOSFETs. Bias Temperature Instability from charge trapping in the gate dielectric causes threshold voltage drift, which in SiC affects some of the key temperature sensitive electrical parameters including ON-state resistance, body diode forward voltage as well as the current commutation rate. This paper reviews the impact of bias temperature instability on the accurate junction temperature measurement using temperature sensitive electrical parameters in SiC MOSFETs