Research progress on porous carbon materials

Tongzhou Wang; Hong Wang

doi:10.1360/N032018-00217

SCIENTIA SINICA Chimica

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SCIENTIA SINICA Chimica, Volume 49 , Issue 5 : 729-740(2019) https://doi.org/10.1360/N032018-00217

Research progress on porous carbon materials

Tongzhou Wang , Hong Wang ^*

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ReceivedOct 4, 2018
AcceptedNov 16, 2018
PublishedFeb 28, 2019

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Abstract

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国家自然科学基金(21875119)

porous carbon materials

polymer precursors

heteroatoms doping

synthetic methods

References

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Figure 1
Functionalized micro/mesoporous carbon materials: synthesis and applications [21] (color online).
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Figure 2
Schematic illustrating preparation of POMC and corresponding SEM and TEM images of POMC [42] (color online).
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Figure 3
Illustration of the formation of gyroidal mesoporous carbon networks through decomposition of the triblock terpolymer [49] (color online).
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Figure 4
Formation and structure of hierarchically structured nitrogen-doped porous carbon membranes [54] (color online).
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Figure 5
Photographs showing the processing of PFCAs under different hypersaline conditions [63] (color online).
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Figure 6
Schematic illustration of the synthetic process of HNPCs using CC as the precursor, urea as the nitrogen source and NaOH solution as the solvent and activation agent [79] (color online).
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Figure 7
A schematic illustrating the formation mechanism of BOMCs [86] (color online).
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Figure 8
The synthetic process of Pt/POMCs [29] (color online).
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Figure 9
Cartoon illustrating the synthetic process of OMC-S [90] (color online).
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Figure 10
Hollow carbon nanoparticles of controllable size and morphology by hydrothermal treatment [93] (color online).
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Figure 11
Synthesis of flexible porous CNF via facile heat treatment of electrospun PAN/DMSO₂ nanofibers and their applications for CDI desalination [97] (color online).
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Figure 12
Nitrogen-doped hierarchically porous carbon membranes being used as electrode for conversion of N₂ to NH₃ under ambient conditions [105] (color online).

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