STW58N60DM2AG

STW58N60DM2AG is a high-performance, 600V N-channel Power MOSFET manufactured by STMicroelectronics, designed for efficient power conversion and switching applications. It features a low on-resistance of 0.13 ohms at VGS = 10V, enabling minimal conduction losses and high energy efficiency in demanding environments. The device utilizes advanced trench technology to optimize gate charge and reduce switching losses, making it ideal for high-frequency operations such as in switch-mode power supplies (SMPS), DC-DC converters, and motor drives. This MOSFET offers robust thermal performance with a maximum junction temperature of 175°C and is housed in a TO-247 package, which provides excellent heat dissipation and mechanical reliability. Its enhanced avalanche ruggedness and safe operating area (SOA) ensure stable operation under transient overcurrent or voltage conditions, improving system safety and longevity. The device also includes a built-in anti-parallel diode that supports freewheeling current paths in inductive load circuits, simplifying circuit design and reducing component count. Designed for industrial and consumer applications, the STW58N60DM2AG is widely used in power supplies for servers, telecom infrastructure, and renewable energy systems like solar inverters. It meets stringent standards for electromagnetic compatibility (EMC) and operates reliably across a wide range of environmental conditions, including high humidity and extended temperature cycles. The low gate threshold voltage (typically 2–4V) allows easy drive compatibility with standard logic-level controllers, minimizing the need for additional driver circuits. With a maximum drain current of 58A at 25°C and a continuous drain current rating of 35A at 100°C, this MOSFET delivers strong performance even under heavy load conditions. Its high breakdown voltage ensures reliable operation in high-voltage DC links, while its optimized RDS(on) × Qg product enables faster switching speeds and reduced total power loss. These characteristics make it well-suited for energy-efficient designs where compact size, high efficiency, and long-term reliability are critical.