Nengjie Cao scite author profile

It is a great challenge to develop efficient room‐temperature sensing materials and sensors for nitric oxide (NO) gas, which is a biomarker molecule used in the monitoring of inflammatory respiratory diseases. Herein, Hemin (Fe (III)‐protoporphyrin IX) is introduced into the nitrogen‐doped reduced graphene oxide (N‐rGO) to obtain a novel sensing material HNG‐ethanol. Detailed XPS spectra and DFT calculations confirm the formation of carbon–iron bonds in HNG‐ethanol during synthesis process, which act as electron transport channels from graphene to Hemin. Owing to this unique chemical structure, HNG‐ethanol exhibits superior gas sensing properties toward NO gas (Ra/Rg = 3.05, 20 ppm) with a practical limit of detection (LOD) of 500 ppb and reliable repeatability (over 5 cycles). The HNG‐ethanol sensor also possesses high selectivity against other exhaled gases, high humidity resistance, and stability (less than 3% decrease over 30 days). In addition, a deep understanding of the gas sensing mechanisms is proposed for the first time in this work, which is instructive to the community for fabricating sensing materials based on graphene‐iron derivatives in the future.

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Understanding the effect of antisolvent on processing window and efficiency for large-area flexible perovskite solar cells

Chen

Jiang

Feng

et al. 2021

Materials Today Physics

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Where is the best substitution position for amino groups on carbon dots: a computational strategy toward long-wavelength red emission

et al. 2021

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Three-Dimensional Graphene-Based Foams with “Greater Electron Transferring Areas” Deriving High Gas Sensitivity

Chen

Wang

Cao

et al. 2021

ACS Appl. Nano Mater.

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Graphene foams are promising three-dimensional (3D) architectures with the combination of the intrinsic nature of graphene and unique cellular structures for various realms. Herein, a facile technique is developed by combining supramolecular assembly with lyophilization to functionalize graphene with donor−π-acceptor (D−π-A) molecules and then massively transform the two-dimensional (2D) plane nanosheets into 3D foams. The as-prepared gas sensors work at room temperature (RT) and reveal comprehensive gas sensing performance with an ultrahigh response (R a/R g = 3.2, 10 ppm), excellent selectivity, and reliable repeatability toward NO2. Notably, a gas sensing enhancement mechanism with density functional theory (DFT) calculations is proposed to unravel the synergetic effect of the “Greater Electron Transferring Area” and the specific 3D foam structure for the enhancement of charge transfer and NO2 adsorption. The combination of supramolecular assembly and the lyophilization technique provides a strategy to prepare 3D architectural graphene-based materials for high-performance gas sensors and chemical trace detectors.

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Nengjie Cao

Practical room temperature formaldehyde sensing based on a combination of visible-light activation and dipole modification

CarbonIron Electron Transport Channels in Porphyrin–Graphene Complex for ppb‐Level Room Temperature NO Gas Sensing

Understanding the effect of antisolvent on processing window and efficiency for large-area flexible perovskite solar cells

Where is the best substitution position for amino groups on carbon dots: a computational strategy toward long-wavelength red emission

Three-Dimensional Graphene-Based Foams with “Greater Electron Transferring Areas” Deriving High Gas Sensitivity

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