ON Semiconductor MM3Z2V4T1G Zener Diode

The ON Semiconductor MM3Z2V4T1G is a high-quality Zener diode designed for providing excellent voltage regulation with a nominal Zener voltage of 2.4 volts. This diode is part of the MM3Z series that are known for their reliability and consistency in performance. It comes in a convenient surface-mount SOD-323 package, making it suitable for high-density mounting and thus ideal for a wide range of electronic applications.

With a power dissipation of 300mW, the MM3Z2V4T1G is capable of sustaining a moderate amount of power, making it suitable for use in various circuit designs that require voltage regulation or reference. This Zener diode features a tight voltage tolerance, which ensures precise voltage clamping in the event of over-voltage conditions, thus providing excellent circuit protection.

The ON Semiconductor MM3Z2V4T1G has a standard Zener impedance and is designed to operate efficiently within a broad operating temperature range from -55°C to +150°C. This wide temperature range assures that the device will function reliably in extreme environmental conditions, making it versatile for use in both commercial and industrial applications.

As with many of ON Semiconductor's components, the MM3Z2V4T1G is RoHS compliant, meaning it adheres to strict environmental standards by avoiding the use of hazardous substances. This compliance ensures that the product is suitable for use in environmentally sensitive applications and aligns with global environmental regulations.

Applications for this Zener diode are diverse and include voltage regulation for small power supplies, protection circuits in consumer electronics, and as a reference voltage in various analog circuits. Its small package size and low leakage current make it an excellent choice for portable devices where power efficiency is crucial.

Overall, the MM3Z2V4T1G from ON Semiconductor is a robust and reliable component that offers designers a compact, efficient solution for voltage regulation and protection needs in their electronic circuits.