Bin Quan scite author profile

A novel FeCo nanoparticle embedded nanoporous carbon composite (Fe-Co/NPC) was synthesized via in situ carbonization of dehydro-ascorbic acid (DHAA) coated Fe3O4 nanoparticles encapsulated in a metal-organic framework (zeolitic imidazolate framework-67, ZIF-67). The molar ratio of Fe/Co significantly depends on the encapsulated content of Fe3O4 in ZIF-67. The composites filled with 50 wt% of the Fe-Co/NPC-2.0 samples in paraffin show a maximum reflection loss (RL) of -21.7 dB at a thickness of 1.2 mm; in addition, a broad absorption bandwidth for RL < -10 dB which covers from 12.2 to 18 GHz can be obtained, and its minimum reflection loss and bandwidth (RL values exceeding -10 dB) are far greater than those of commercial carbonyl iron powder under a very low thickness (1-1.5 mm). This study not only provides a good reference for future preparation of carbon-based lightweight microwave absorbing materials but also broadens the application of such kinds of metal-organic frameworks.

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Defect Engineering in Two Common Types of Dielectric Materials for Electromagnetic Absorption Applications

Quan

Shi

Ong

et al. 2019

Adv Funct Materials

532

162

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(1 of 10)Dielectric materials are greatly desired for electromagnetic absorption applications. Lots of research shows that conduction loss and polarization are two of the most important factors determining complex permittivity. However, the detailed dissipation mechanisms for the improved microwave absorption performance are often based on semiempirical rules, lacking practical data relationships between conduction loss/polarization and dielectric behaviors. Here, a strategy of introducing point defects is used to understand such underlying relationships, where polarizability and conductivity are adjustable by manipulating oxygen deficiency or heteroatoms. Based on first principles calculations and the applied oxygendeficient strategy, dielectric polarization is shown to be dominant in determining the permittivity behaviors in semiconductors. Meanwhile, the presented nitrogen doping strategy shows that conduction loss is dominant in determining the permittivity behavior in graphitized carbon materials. The validity of the methods for using point defects to explore the underlying relations between conduction loss/polarization and dielectric behaviors in semiconductor and graphitized carbon are demonstrated for the first time, which are of great importance in optimizing the microwave absorption performance by defect engineering and electronic structure tailoring.

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Dielectric polarization in electromagnetic wave absorption: Review and perspective

Quan

Liang

et al. 2017

Journal of Alloys and Compounds

517

154

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Metal–organic-frameworks derived porous carbon-wrapped Ni composites with optimized impedance matching as excellent lightweight electromagnetic wave absorber

Liu

Shao

et al. 2017

Chemical Engineering Journal

519

138

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Bin Quan

Thermal conversion of an Fe₃O₄@metal–organic framework: a new method for an efficient Fe–Co/nanoporous carbon microwave absorbing material

Defect Engineering in Two Common Types of Dielectric Materials for Electromagnetic Absorption Applications

Dielectric polarization in electromagnetic wave absorption: Review and perspective

Metal–organic-frameworks derived porous carbon-wrapped Ni composites with optimized impedance matching as excellent lightweight electromagnetic wave absorber

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About

Bin Quan

Thermal conversion of an Fe3O4@metal–organic framework: a new method for an efficient Fe–Co/nanoporous carbon microwave absorbing material

Defect Engineering in Two Common Types of Dielectric Materials for Electromagnetic Absorption Applications

Dielectric polarization in electromagnetic wave absorption: Review and perspective

Metal–organic-frameworks derived porous carbon-wrapped Ni composites with optimized impedance matching as excellent lightweight electromagnetic wave absorber

Contact Info

Product

Resources

About

Thermal conversion of an Fe₃O₄@metal–organic framework: a new method for an efficient Fe–Co/nanoporous carbon microwave absorbing material