Light-activated gas sensing: a perspective of integration with micro-LEDs and plasmonic nanoparticles

Light-activated gas sensors have been investigated for their superior potential to replace current thermally activated gas sensors, which have several drawbacks for the Internet of Everything application. This review summarizes the various efforts made for the development of light-activated gas sensors and provides an overview of their progress. The light-activated gas sensing properties of metal oxides, 2D materials, and other candidate materials are summarized. As strategies to overcome the current challenges of light-activated gas sensors, the effects of nanostructures and crystallographic orientations are discussed. Finally, the incorporation of plasmonic nanoparticles and integration with micro lighte-mitting diodes are proposed for the pathway toward the real application of light-activated gas sensors. This review should offer a broad range of readers a new perspective toward the future development of light-activated gas sensors.

Automated summary

Research on light-activated gas sensors has focused on the development of metal oxides, 2D materials, and other candidate materials, as well as the effects of nanostructures and crystallographic orientations in overcoming challenges. Strategies such as incorporating plasmonic nanoparticles and integrating with micro light-emitting diodes have been proposed for the real-world application of light-activated gas sensors. Overall, this review offers a new perspective on the future development of light-activated gas sensors for a wide range of readers.