鼻のようなセンサーが有毒なアンモニアガスを嗅ぎ分ける(Nose-like sensor sniffs out toxic ammonia gas)

2024-02-01 ロイヤルメルボルン工科大学(RMIT)

＜関連情報＞

• https://www.rmit.edu.au/news/all-news/2024/feb/ammonia-sensor
• https://onlinelibrary.wiley.com/doi/10.1002/adfm.202309342

高性能アンモニアセンサ用の瞬時空気液体金属プリント極薄酸化スズ Instant-in-Air Liquid Metal Printed Ultrathin Tin Oxide for High-Performance Ammonia Sensors

Chung Kim Nguyen, Patrick D. Taylor, Ali Zavabeti, Hamidah Alluhaybi, Samira Almalki, Xiangyang Guo, Mehmood Irfan, Mohammad Al Kobaisi, Samuel J. Ippolito, Michelle J.S. Spencer …
Advanced Functional Materials  Published: 15 November 2023
DOI:https://doi.org/10.1002/adfm.202309342

Abstract

Liquid metal-based printing techniques are emerging as an exemplary platform for harvesting non-layered 2D materials with a thickness down to a few nanometres, leading to an ultra-large surface-area-to-volume ratio that is ideal for sensing applications. In this work, the synthesis of 2D tin dioxide (SnO₂) by exfoliating the surface oxide of molten tin is reported which highlights the enhanced sensing capability of the obtained materials to ammonia (NH₃) gas is reported. It is demonstrated that amperometric gas sensors based on liquid metal-derived 2D SnO₂ nanosheets can achieve excellent NH₃ sensing performance at low temperature (150 °C) with and without UV light assistance. Detection over a wide range of NH₃ concentrations (5–500 ppm) is observed, revealing a limit of detection at the parts per billion (ppb) level. The 2D SnO₂ nanosheets also feature excellent cross-interference performance toward different organic and inorganic gas species, showcasing a high selectivity. Further, ab initio DFT calculations reveal the NH₃ adsorption mechanism is dominated by chemisorption with a charge transfer into 2D SnO₂ nanosheets. In addition, a proof of concept for prototype flexible ammonia sensors is demonstrated by depositing 2D SnO₂ on a polyimide substrate, signifying the high potential of employing liquid metal printed SnO₂ for realizing wearable gas sensors.