“Scalable film fabrication is key to meeting the requirements of next-generation optoelectronic devices. Our progress in this work ingeniously avoids the difficulties with traditional thin film preparation techniques, making it more broadly applicable for practical use,” said Professor Johnny Ho, Associate Vice-President (Enterprise) and Professor in the Department of Materials Science and Engineering at CityU, who led the study.

The key advantage of the low-temperature synthesis technique developed in this study is its applicability to various flexible substrates. The research team also made an intriguing discovery regarding the thermal effect of these substrates on the optoelectronic response of the resulting thermoelectric thin films. This finding opens up opportunities for achieving wide-spectrum detection capabilities.

The demand for flexible optoelectronic devices has spurred the need for advanced techniques with high throughput and low processing temperatures. However, when crystalline films are required, additional high-temperature processes are required. This requirement poses significant challenges when working with thermally unstable substrates and other device components.

To overcome these obstacles, the research team developed a novel pulse irradiation synthesis method that achieves both a low processing temperature and an ultra-short reaction time, surpassing the capabilities of conventional techniques.

With the new method for preparing metal sulfide thin films at low temperatures, these detectors can now achieve higher performance on suitable flexible substrates. This creates exciting possibilities for thermal imaging applications in security monitoring, fire detection, military surveillance, and other fields. Additionally, the photothermoelectric effect allows for the conversion of invisible infrared light into electrical signals, paving the way for applications in high-speed communications and optical signal processing.

Looking ahead, the research team's plans involve primarily optimizing performance and adjusting parameters, expanding material systems, and exploring the integration and feasibility of practical applications. These efforts aim to further enhance the potential of low-temperature synthesized metallic inorganic compound thin films and pave the way for the realization of advanced flexible optoelectronic devices.