Graphene‐Based Heterostructure Composite Sensing Materials for Detection of Nitrogen‐Containing Harmful Gases

Graphene‐based heterostructure composite is a new type of advanced sensing material that includes composites of graphene with noble metals/metal oxides/metal sulfides/polymers and organic ligands. Exerting the synergistic effect of graphene and noble metals/metal oxides/metal sulfides/polymers and o...

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Bibliographic Details
Published in:Advanced functional materials 2021-10, Vol.31 (41), p.n/a
Main Authors: Feng, Qiuxia, Huang, Baoyu, Li, Xiaogan
Format: Article
Language:English
Subjects:
Ammonia
composite sensing materials
Electrical properties
Gas sensors
Gases
Graphene
graphene‐based heterostructures
Heterostructures
Ligands
Materials science
Metal oxides
Metal sulfides
Metals
NH 3 sensors
Nitrogen
Nitrogen dioxide
NO 2 sensors
Noble metals
Parameter sensitivity
Polymers
Selectivity
Synergistic effect
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Summary:Graphene‐based heterostructure composite is a new type of advanced sensing material that includes composites of graphene with noble metals/metal oxides/metal sulfides/polymers and organic ligands. Exerting the synergistic effect of graphene and noble metals/metal oxides/metal sulfides/polymers and organic ligands is a new way to design advanced gas sensors for nitrogen‐containing gas species including NH3 and NO2 to solve the problems such as poor stability, high working temperature, poor recovery, and poor selectivity. Different fabrication methods of graphene‐based heterostructure composite are extensively studied, enabling massive progress in developing chemiresistive‐type sensors for detecting the nitrogen‐containing gas species. With the components of noble metals/metal oxides/metal sulfides/polymers and organic ligands which are composited with graphene, each material has its attractive and unique electrical properties. Consequently, the corresponding composite formed with graphene has different sensing characteristics. Furthermore, working ambient gas and response type can affect gas‐sensitive characteristic parameters of graphene‐based heterostructure composite sensing materials. Moreover, it requires particular attention in studying gas sensing mechanism of graphene‐based heterostructure composite sensing materials for nitrogen‐containing gas species. This review focuses on related scientific issues such as material synthesis methods, sensing performance, and gas sensing mechanism to discuss the technical challenges and several perspectives. This review focuses on related scientific issues such as the material synthesis methods, sensing performance, and gas sensing mechanism of graphene based heterostructure composite sensing materials for application of nitrogen‐containing gas (NH3/NO2) sensors to discuss the technical challenges and several perspectives.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202104058