Ultrafast Self‐Powered Ti–Zn–N Photodetector‐Based Optocoupler for Power Electronics Applications

This study presents an early exploration into the application of a self‐powered photodetector based on titanium zinc nitride (TiZnN) films in power electronics, aiming to overcome inherent limitations of conventional optocouplers such as low switching speed and specific operating voltage requirements. The fabricated device demonstrates excellent performance metrics, including photosensitivity of 136, the responsivity of 3.22 mA W−1 at −8 V bias, and a peak detectivity of 1.76 × 108 Jones at 0 V bias. Remarkably, ultrafast rise (τs) and decay times (τd) of 0.11 and 0.10 ms, respectively, are achieved, alongside broad‐band spectral absorption characteristics. Experimental validation showcases the efficacy of the TiZnN‐based optocoupler in practical applications, notably in power electronics triggerable relay systems and AC–AC converters. Leveraging the self‐powering capability inherent to the TiZnN photodetector, this optocoupler eliminates external power source dependencies, thereby enhancing its versatility and applicability in diverse electronic systems. The rapid response time of the device and broad spectral absorption further underscore its suitability for high‐speed signal transmission across varied operating conditions. This research paves a path for developing stable, cost‐effective, and self‐powered ultrafast optocouplers, eliminating concerns about compromising electrical signal transit. These advancements hold significant implications for enhancing electronic system performance, reliability, and functionality in critical applications. A self‐powered photodetector with ternary nitride semiconductor films for power electronics applications, surpassing conventional optocoupler limitations, is demonstrated. It achieves impressive metrics: photosensitivity (136), responsivity (3.22 mA W−1 at −8 V), detectivity (1.76 × 108 Jones at 0 V), and ultrafast response times (0.11 ms rise, 0.10 ms decay). Experimental validation highlights its self‐powering capability and broad spectral absorption for high‐speed signal transmission.