Assembly of Core/Shell Nanospheres of Amorphous Hemin/Acetone-Derived Carbonized Polymer with Graphene Nanosheets for Room-Temperature NO Sensing

Implementing parts per billion-level nitric oxide (NO) sensing at room temperature (RT) is still in extreme demand for monitoring inflammatory respiratory diseases. Herein, we have prepared a kind of core–shell structural Hemin-based nanospheres (Abbr.: Hemin-nanospheres, defined as HNSs) with the c...

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Published in:ACS applied materials & interfaces 2022-11, Vol.14 (47), p.53193-53201
Main Authors: Wang, Jianqiang, Gao, Yixun, Chen, Fengjia, Zhang, Lulu, Li, Hao, de Rooij, Nicolaas Frans, Umar, Ahmad, Lee, Yi-Kuen, French, Paddy J., Yang, Bai, Wang, Yao, Zhou, Guofu
Format: Article
Language:English
Subjects:
Functional Nanostructured Materials (including low-D carbon)
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Summary:Implementing parts per billion-level nitric oxide (NO) sensing at room temperature (RT) is still in extreme demand for monitoring inflammatory respiratory diseases. Herein, we have prepared a kind of core–shell structural Hemin-based nanospheres (Abbr.: Hemin-nanospheres, defined as HNSs) with the core of amorphous Hemin and the shell of acetone-derived carbonized polymer, whose core–shell structure was verified by XPS with argon-ion etching. Then, the HNS-assembled reduced graphene oxide composite (defined as HNS-rGO) was prepared for RT NO sensing. The acetone-derived carbonized polymer shell not only assists the formation of amorphous Hemin core by disrupting their crystallization to release more Fe–N4 active sites, but provides protection to the core. Owing to the unique core–shell structure, the obtained HNS-rGO based sensor exhibited superior RT gas sensing properties toward NO, including a relatively higher response (R a/R g = 5.8, 20 ppm), a lower practical limit of detection (100 ppb), relatively reliable repeatability (over 6 cycles), excellent selectivity, and much higher long-term stability (less than a 5% decrease over 120 days). The sensing mechanism has also been proposed based on charge transfer theory. The superior gas sensing properties of HNS-rGO are ascribed to the more Fe–N4 active sites available under the amorphous state of the Hemin core and to the physical protection by the shell of acetone-derived carbonized polymer. This work presents a facile strategy of constructing a high-performance carbon-based core–shell nanostructure for gas sensing.
ISSN:1944-8244
1944-8252
DOI:10.1021/acsami.2c16769