Litcius/Paper detail

Black Phosphorus Nanosheet/Tin Oxide Quantum Dot Heterostructures for Highly Sensitive and Selective Trace Hydrogen Sulfide Sensing

Yanjie Wang, Zhihao Hu, Jing Li, Hongchao Zhao, Ruijie Zhang, Yi Ou, Lei Xie, Jun Yang, Cheng Zou, Yong Zhou

2023ACS Applied Nano Materials37 citationsDOI

Abstract

Conductometric detection of hydrogen sulfide (H 2 S) gas is highly desired in the fields of environmental protection and noninvasive human health assessment due to its unique merits of real-time monitoring, low cost, and high miniaturization. In this regard, semiconducting metal oxides, such as tin oxide (SnO 2 ), have been extensively employed for H 2 S detection but suffer from constrained sensitivity, elevated operation temperature, and poor selectivity. To overcome these drawbacks, mixed-dimensional heterostructures of two-dimensional (2D) black phosphorus (BP) nanosheet-templated zero-dimensional (0D) SnO 2 quantum dots (QDs) (BP/SnO 2 ) were prepared in this work for trace H 2 S detection. The constituent ratio-optimized BP/SnO 2 sensors showed a high response of 233.8 and swift response/recovery speeds of 16.4/9.5 s toward 5 ppm H 2 S and ultralow energy consumption at a relatively low operation temperature (10 mW@130 °C), rivaling or surpassing that of most of the sensors in recent academic reports and commercial products. Moreover, excellent repeatability, long-term stability, and selectivity were demonstrated. When exposed to 5 ppm H 2 S under 80% relative humidity, the sensor displayed a 75% response retention with respect to the dry case, revealing a favorable humidity tolerance. Furthermore, the BP/SnO 2 sensors outperformed their reduced graphene oxide (rGO)- and molybdenum disulfide (MoS 2 )-templated counterparts in terms of response intensity and response/recovery speeds. Benefiting from the abundant p–n heterojunctions and sufficient material utility within the mixed-dimensional heterostructures, the as-prepared BP/SnO 2 sensors showcased brilliant application prospects for energy-saving and portable H 2 S detection systems.

Topics & Concepts

NanosheetHeterojunctionGrapheneMaterials scienceMolybdenum disulfideQuantum dotTin oxideHydrogen sulfideOxideSelectivityNanotechnologyOptoelectronicsChemistrySulfurCatalysisMetallurgyBiochemistryGas Sensing Nanomaterials and SensorsAnalytical Chemistry and Sensors2D Materials and Applications
Black Phosphorus Nanosheet/Tin Oxide Quantum Dot Heterostructures for Highly Sensitive and Selective Trace Hydrogen Sulfide Sensing | Litcius