ON Semiconductor MMSZ2V4T1G Zener Diode

The ON Semiconductor MMSZ2V4T1G is a high-quality Zener diode designed for providing a reliable voltage reference. This electronic component is a must-have in any circuit where voltage regulation and stabilization are required. With its precise voltage control and low leakage current, it is an excellent choice for power supply circuits, voltage monitors, and other applications where a stable Zener voltage is needed.

Key Features

• Standard Zener Breakdown Voltage Range: The MMSZ2V4T1G has a nominal Zener voltage of 2.4V, making it suitable for various low-voltage applications.
• High Stability: It offers excellent stability and reliability over time, ensuring consistent performance throughout its lifespan.
• Low Leakage Current: This Zener diode boasts a low leakage current, which enhances the overall efficiency of the circuit by reducing power loss.
• Surface Mount Package: The SOD-123 package is compact and suitable for high-density PCB designs, making it ideal for modern electronic applications.
• Power Dissipation: With a power dissipation of 500 mW, this diode can handle moderate amounts of power, suitable for a range of electronic applications.
• PPM/°C Voltage Change: The device has a low voltage change with temperature, ensuring stable operation over a wide range of temperatures.
• RoHS Compliant: The MMSZ2V4T1G is compliant with RoHS standards, minimizing the environmental impact by avoiding the use of certain hazardous substances in its construction.

Applications

The MMSZ2V4T1G is versatile and can be used in a variety of electronic circuits. Some common applications include:

• Voltage regulation modules
• Overvoltage and surge protection circuits
• Switching power supplies
• Consumer electronics
• Computer motherboards
• Industrial control systems

In summary, the ON Semiconductor MMSZ2V4T1G is a robust and efficient Zener diode that offers precise voltage regulation, making it an essential component for designers looking to ensure the stability and reliability of their electronic circuits.