Nanostructured Gas Sensors: From Air Quality and Environmental Monitoring to Healthcare and Medical Applications

In the last decades, nanomaterials have emerged as multifunctional building blocks for the development of next generation sensing technologies for a wide range of industrial sectors including the food industry, environment monitoring, public security, and agricultural production. The use of advanced nanosensing technologies, particularly nanostructured metal-oxide gas sensors, is a promising technique for monitoring low concentrations of gases in complex gas mixtures. However, their poor conductivity and lack of selectivity at room temperature are key barriers to their practical implementation in real world applications. Here, we provide a review of the fundamental mechanisms that have been successfully implemented for reducing the operating temperature of nanostructured materials for low and room temperature gas sensing. The latest advances in the design of efficient architecture for the fabrication of highly performing nanostructured gas sensing technologies for environmental and health monitoring is reviewed in detail. This review is concluded by summarizing achievements and standing challenges with the aim to provide directions for future research in the design and development of low and room temperature nanostructured gas sensing technologies.

Automated summary

Nanomaterials show great potential as multifunctional building blocks for next generation sensing technologies, especially in gas sensing applications. Nanostructured metal-oxide gas sensors are promising for detecting low concentrations of gases, but their conductivity and selectivity at room temperature remain key challenges in practical applications. Advances in reducing the operating temperature of nanostructured materials for gas sensing and designing efficient architecture for highly performing sensors are reviewed in detail, with a focus on environmental and health monitoring.