With the performance advantages of a Silicon Carbide (SiC) Schottky Barrier diode, power electronics systems can expect to meet higher efficiency standards than Si-based solutions, while also reaching higher frequencies and power densities. SiC diodes can be easily paralleled to meet various application demands, without concern of thermal runaway. In combination with the reduced cooling requirements and improved thermal performance of SiC products, SiC diodes are able to provide lower overall system costs in a variety of diverse applications.
Features
Low Forward Voltage (VF) Drop with Positive Temperature Coefficient
Zero Reverse Recovery Current / Forward Recovery Voltage
Temperature-Independ
ent Switching Behavior
Automotive Qualified (AEC Q101) and PPAP Capable
Applications
Automotive and traction power convertion
Interleaved or Bridgeless PFC
DC/DC On Board Battery Chargers
Boost for PFC & DC-DC Stages
AC/DC On Board Chargers
PFC Output Rectification
With the performance advantages of a Silicon Carbide (SiC) Schottky Barrier diode, power electronics systems can expect to meet higher efficiency standards than Si-based solutions, while also reaching higher frequencies and power densities. SiC diodes can be easily paralleled to meet various application demands, without concern of thermal runaway. In combination with the reduced cooling requirements and improved thermal performance of SiC products, SiC diodes are able to provide lower overall system costs in a variety of diverse applications.
Features
- Low Forward Voltage (VF) Drop with Positive Temperature Coefficient
- Zero Reverse Recovery Current / Forward Recovery Voltage
- Temperature-Independent Switching Behavior
- Automotive Qualified (AEC Q101) and PPAP Capable
Applications
- Automotive and traction power convertion
- Interleaved or Bridgeless PFC
- DC/DC On Board Battery Chargers
- Boost for PFC & DC-DC Stages
- AC/DC On Board Chargers
- PFC Output Rectification
