In situ growth of globular MnO2 nanoflowers inside hierarchical porous mangosteen shells-derived carbon for efficient electromagnetic wave absorber

•Biomass derived MnO2@PMSC absorbers were fabricated via two-step carbonization and hydrothermal synthesis.•The dielectric behaviors of PMSC can be conveniently modulated by controlling the MnO2 content.•Rational component and structural design of MnO2@PMSC provide multiple polarization and multiple...

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Bibliographic Details
Published in:Journal of alloys and compounds 2022-05, Vol.903, p.163826, Article 163826
Main Authors: Xu, Pan, Fang, Jiyong, He, Hongru, Yue, Xigui
Format: Article
Language:English
Subjects:
Absorbers
Absorption
Biomass
Carbon
Electromagnetic radiation
Electromagnetic wave absorption
Globular MnO2 nanoflowers
Impedance matching
In situ growth
Manganese dioxide
Mangosteen shells carbon
Structural hierarchy
Walls
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Summary:•Biomass derived MnO2@PMSC absorbers were fabricated via two-step carbonization and hydrothermal synthesis.•The dielectric behaviors of PMSC can be conveniently modulated by controlling the MnO2 content.•Rational component and structural design of MnO2@PMSC provide multiple polarization and multiple attenuation for EMW.•EMW absorption properties were raised by the synergistic effect between PMSC and MnO2. The mangosteen shells-derived hierarchically porous carbon embedded with globular MnO2 nanoflowers (MnO2@PMSC) has demonstrated great potential for application in the field of electromagnetic wave absorption. [Display omitted] Developing electromagnetic wave (EMW) absorbing materials with reasonable structure and composition is of great significance. In this work, the porous mangosteen shells-derived carbon embedded with globular MnO2 nanoflowers (MnO2@PMSC) were fabricated via two-step carbonization and subsequent hydrothermal synthesis. The biomass-based carbon with highly opened hierarchical porous structures provides abundant in-situ growth points for globular MnO2 nanoflowers, ensuring that they could nucleate in situ and grow inside the carbon walls. It is worth noting that the EMW absorption properties of the absorber can be efficiently enhanced by tuning the contents of globular MnO2 nanoflowers. The as-synthesized optimal sample (MnO2@PMSC-2) exhibits superior EMW absorption performances with the minimum reflection loss (RLmin) value of −54.61 dB and wide effective absorption bandwidth (EAB) of 4.10 GHz at 1.80 mm. The excellent EMW absorption performance is attributed to the multiple reflection and scattering caused by the hierarchical porous structures of the biomass carbon and the flower–like structure of MnO2, strong polarization effects between MnO2 and carbon walls, as well as the good impedance matching condition achieved by the strong synergy between the two components. These results indicated that MnO2@PMSC-2 is a potential electromagnetic wave absorber.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2022.163826