ON Semiconductor MBR41H100CT Schottky Rectifier

The MBR41H100CT is a high-performance Schottky rectifier designed by ON Semiconductor, renowned for its efficiency and reliability in power management applications. This robust component is engineered to offer low forward voltage drop while providing superior reverse leakage characteristics, making it an ideal choice for high-frequency and energy-sensitive circuits.

Key Features

• High Surge Capacity: The device is capable of handling high surge currents, which is critical for applications that may experience unexpected overloads.
• Low Power Loss: With its low forward voltage drop, the MBR41H100CT minimizes power loss, enhancing overall system efficiency and reducing thermal challenges.
• High Junction Temperature: This rectifier can operate at a junction temperature of up to 150°C, which is suitable for high-temperature environments.
• Dual Diode Configuration: The component features a common cathode dual diode configuration, which allows for its use in various configurations like parallel or series arrangements.

Electrical Characteristics

• Forward Continuous Current: It has a high forward continuous current rating of 40A, which makes it capable of handling significant power levels.
• Peak Repetitive Reverse Voltage: With a peak repetitive reverse voltage of 100V, it can be used in a wide range of applications that require a high breakdown voltage.
• Fast Switching Speed: The device is designed for fast switching, reducing the transition losses in high-frequency applications.

Applications

• Switching power supplies
• Converters
• Free-wheeling diodes
• Reverse battery protection
• DC-DC converters

The MBR41H100CT is presented in a TO-220AB package, known for its ease of installation and robustness. Its package is designed to optimize the thermal performance and improve the overall reliability of the device. With its combination of high efficiency, thermal stability, and durability, the MBR41H100CT Schottky rectifier from ON Semiconductor is a superior choice for designers looking to enhance the performance of their power management systems.