The Art of Integrated Functionalization: Super Stable Black Phosphorus Achieved through Metal‐Organic Framework Coating

Black phosphorus (BP) is a promising 2D nanomaterial with a great potential in various areas, while its intrinsic instability greatly suppresses practical applications, particularly under harsh conditions (e.g., high temperature). Herein, BP functionalization with Al ion is achieved in an integrated...

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Bibliographic Details
Published in:Advanced functional materials 2020-07, Vol.30 (27), p.n/a
Main Authors: Han, Bin, Duan, Zaihua, Xu, Jun, Zhu, Yuxiang, Xu, Qingchi, Wang, Hao, Tai, Huiling, Weng, Jian, Zhao, Yanli
Format: Article
Language:English
Subjects:
Aluminum
black phosphorus
Chemical properties
Crosslinking
Electron density
gas sensor
Gas sensors
High temperature
Materials science
Metal-organic frameworks
Nanomaterials
Nitrogen dioxide
Operating temperature
Phosphorus
Selectivity
Sensors
stability
surface functionalization
Thermal stability
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Summary:Black phosphorus (BP) is a promising 2D nanomaterial with a great potential in various areas, while its intrinsic instability greatly suppresses practical applications, particularly under harsh conditions (e.g., high temperature). Herein, BP functionalization with Al ion is achieved in an integrated manner through MIL‐53 metal‐organic framework (MOF) coating, which greatly improves both ambient and thermal stability of BP. For the obtained MIL‐53 coated BP (BP@MIL‐53), abundant Al ion within MIL‐53 interacts with the lone pair electrons of BP, and subsequently decreases the BP surface electron density, reducing the reactivity of BP toward O2 and H2O. The MOF growth crosslinks the Al ion on the BP surface, and achieves integrated functionalization to withstand the detachment of individual Al ion from the BP surface. The noncovalent bond of BPAl and highly porous structure of MIL‐53 preserve the physical/chemical properties of BP to the maximum, and render BP@MIL‐53 with super‐stability. This functionalization strategy extends the applications of BP based devices under high temperature conditions. As a proof of concept, BP@MIL‐53 is further utilized as a NO2 gas sensor under relatively high operating temperatures. The BP@MIL‐53 sensor exhibits fast response, outstanding selectivity, and high recovery dynamic process in contrast to bare BP sensor. Black phosphorus functionalization with Al ion is achieved through metal‐organic framework coating, enabling the obtained hybrid materials to serve as a NO2 sensor with high stability, precise sensitivity, fast response time, and excellent reversibility under high temperature conditions.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202002232