Room Temperature VOC Detection Using Light-Driven Metal Oxide Heterojunctions: Principles, Challenges, and Prospects

Abstract

Volatile organic compounds (VOCs) are a very important class of pollutants and biomarkers of diseases, which require the development of highly sensitive sensors. This review article critically discusses the recent advances in the development of semiconductor metal oxide (SMO) heterojunction-based chemiresistive sensors for VOC detection, particularly with the use of light-activated sensing mechanisms to improve the performance parameters of sensitivity, selectivity, response time, and stability. The basic sensing mechanisms, such as band engineering, charge transfer processes, room-temperature sensing, and heterojunction designs, are comprehensively reviewed to understand their role in gas adsorption and sensing response modulation. This review article also discusses the conventional limitations of pristine SMO sensors, such as temperature limitations and drift effects, and how the use of heterojunctions along with ultraviolet and visible light activation can overcome these limitations and improve the performance of gas sensors. The integration of these sensors in smart devices and Internet of Things (IoT) applications is reviewed, with special emphasis on wearable and packaging devices for environmental and food quality monitoring. Moreover, the application potential of these sensor systems in medical diagnostics is highlighted by examples of VOC biomarkers for diabetes and lung cancer. The critical challenges in the current research are also pointed out, including the need for improved stability in different humidity conditions, selectivity, and scalable fabrication techniques. The review concludes by outlining the future directions, including hybrid materials, flexible electronics, and artificial intelligence-assisted, IoT-enabled sensor development providing a forward-looking roadmap for intelligent and advanced VOC sensing technologies towards real-world applications. This thorough review is intended to provide a basis for future innovations in materials-based sensor technologies, in line with the emerging challenges in society.