Effect of flame partition and flight behaviors on intrinsic characteristics and absorption properties of hollow ceramic microspheres

Effect of flame partition and flight behaviors on intrinsic characteristics and absorption properties of hollow ceramic microspheres

•High-speed photography used for flame field partition and flight combustion behaviors.•Relationship between intrinsic characteristics of HMCMs and flame characters was investigated.•Relationship between intrinsic characteristics and absorbing properties was established. Fe–MnO2–Fe2O3–sucrose–epoxy...

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Bibliographic Details
Published in:Journal of alloys and compounds Vol. 608; pp. 170 - 179
Main Authors: Lou, Hongfei, Wang, Jianjiang, Xu, Baocai, Zhao, Zhining, Wan, Guoshun, Hou, Yongshen
Format: Journal Article
Language:English
Published: Kidlington Elsevier B.V 25-09-2014
Elsevier
Subjects:
Absorption properties
Bandwidth
Ceramics
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Cross-disciplinary physics: materials science; rheology
Dielectric loss
Dielectric loss and relaxation
Dielectric properties of solids and liquids
Dielectrics, piezoelectrics, and ferroelectrics and their properties
Exact sciences and technology
Flame field partition and different flight combustion behaviors of particles
Intrinsic characteristics of HMCMs
Iron
Magnetic properties
Materials science
Materials synthesis; materials processing
Microspheres
Microwave and radio-frequency interactions (excluding resonances)
Optical properties and condensed-matter spectroscopy and other interactions of matter with particles and radiation
Other interactions of matter with particles and radiation
Particle size
Partitions
Physics
Self-reactive quenching technology
Self-reactive quenching technology
Absorption properties
Flame field partition and different flight combustion behaviors of particles
Intrinsic characteristics of HMCMs
Combustion synthesis
Particle size
Electrical conductivity
Vacancies
Iron oxide
Epoxy resin
Iron
Quenching
Microspheres
Hollow shape
Manganese oxides
Microwave absorption
Solid solutions
Transition elements
Dielectric losses
Chemical composition
Dipole moments
Microstructure
Permittivity
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Summary:•High-speed photography used for flame field partition and flight combustion behaviors.•Relationship between intrinsic characteristics of HMCMs and flame characters was investigated.•Relationship between intrinsic characteristics and absorbing properties was established. Fe–MnO2–Fe2O3–sucrose–epoxy resin and self-reactive quenching technology were used to prepare two kinds of hollow multiphase ceramic microspheres (HMCMs). The results obtained by high-speed photography, SEM, XRD and laser particle size analysis showed that the flame field partition (“edge region”, “junction region” and “center region”) and different flight combustion behaviors of particles (“self-burst”, “collision effect” and “self-diminution”) are the main reasons to generate different intrinsic characteristics (particle size, microstructure and chemical composition) between coarse and fine HMCMs. On the one hand, these differences resulted in different electromagnetic parameters. Coarse HMCMs, owing to low resistivity, Fe–Fe3+ dipoles formed and more defects or vacancy, possessed higher dielectric loss. And due to the same main phase (MnFe2O4), the two kinds of HMCMs have close magnetic properties, however, the magnetic loss of fine HMCMs will move to low-frequency which resulted from infinite solid solution formed. On the other hand, different optimal match thickness (dcoarse=2.5mm and dfine=2mm), minimum reflectivity (Rcoarse=−24dB and Rfine=−25dB) and effective absorption bandwidth (fcoarse=4GHz and ffine=4.2GHz) were caused by these differences. This also illustrate that the match thickness will reduce along with the decrease of particle size. In addition, the two kinds of HMCMs belong to dielectric loss dominated material. And in the same thickness (2mm), because of low permittivity of fine HMCMs, the electromagnetic match property was improved to broaden effective absorption bandwidth (4GHz).
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ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2014.04.096