N-doped porous carbon nanoplates embedded with CoS2 vertically anchored on carbon cloths for flexible and ultrahigh microwave absorption

N-doped porous carbon nanoplates embedded with CoS2 vertically anchored on carbon cloths for flexible and ultrahigh microwave absorption

Metal-organic-frameworks (MOF) derived carbon materials are usually utilized as microwave absorbers, however, the practical application of the powders in flexible devices is restricted. Herein, a facile strategy is developed for in-situ vertically grown of Co-MOF precursor on conductive carbon cloth...

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Bibliographic Details
Published in:Carbon (New York) Vol. 163; pp. 348 - 359
Main Authors: Liu, Panbo, Zhu, Chenyu, Gao, Sai, Guan, Cao, Huang, Ying, He, Wenjuan
Format: Journal Article
Language:English
Published: New York Elsevier Ltd 15-08-2020
Elsevier BV
Subjects:
Carbon
Carbon fibers
Carbonization
Cobalt sulfide
Composite materials
Conductivity
CoS2
Electronic devices
Flexible composites
Impedance matching
Metal-organic frameworks
Microwave absorbers
Microwave absorption
Microwave absorption performance
N-doped porous carbon
Nanomaterials
Portable equipment
Substrates
Sulfidation
Thickness
Microwave absorption performance
N-doped porous carbon
CoS2
Flexible composites
Metal-organic-frameworks
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Summary:Metal-organic-frameworks (MOF) derived carbon materials are usually utilized as microwave absorbers, however, the practical application of the powders in flexible devices is restricted. Herein, a facile strategy is developed for in-situ vertically grown of Co-MOF precursor on conductive carbon cloths, followed by the carbonization and sulphidation process. The synthesized flexible composites, in which intertwined carbon cloths act as the skeleton, hierarchical N-doped porous carbon nanoplates anchor on the substrate and CoS2 particles are encapsulated by graphitic carbon, exhibit ultrahigh microwave absorption because of the conductive network, hierarchical porous architecture, enhanced dipolar/interfacial polarization, multi-scattering and promoted impedance matching. The thickness of graphitic carbon can be tuned from 12 layers to 25 layers by adjusting the carbonization temperature and the flexible composites annealed at 700 °C outperform others in terms of microwave absorption performance. Typically, the maximum reflection loss (RL) is up to −59.6 dB at 2.8 mm and the effective bandwidth (RL < −10 dB) reaches as wide as 9.2 GHz with a thickness of 2.5 mm. Consequently, this strategy offers a novel thought for large-scale construction of flexible carbon composites with effective microwave response and the resulted composites possess a promising potential in the practical application of portable microwave absorption electronic devices. [Display omitted]
ISSN:0008-6223
1873-3891
DOI:10.1016/j.carbon.2020.03.041