Orientation growth modulated magnetic-carbon microspheres toward broadband electromagnetic wave absorption

Surface magnetic configurations and electromagnetic responding behaviors can be efficiently modulated by controlling the growth of magnetic materials, which has always been a huge challenge. Here, an in situ orientation growth strategy is developed to build a micron scale Fe3O4-Fe3O4@C heterojunction via applying Kirkendall diffusion to the orientation growth process. Undergoing precipitation and phase transition process, the oriented Fe3O4 octahedron tightly rooted in anisotropy Fe3O4@C body, constructing various magnetic configurations and enhancing stray magnetic field intensity. As-synthesized magnetic-dielectric microspheres exhibited excellent energy conversion capacity toward electromagnetic wave, including strong reflection loss (RL: 40.8 dB, 2.0 mm) and ultra-wide absorption region (similar to 11.04 GHz, similar to 69% of the tested frequency). Essentially, cross-space magnetic coupling enlarges the responding region beyond the material itself and strengthens electromagnetic wave disputation. Local charge density distribution around the grain boundary plays the key role in forming the enhanced interfacial polarization, which is characterized by the off-axis electronic holography. More importantly, the dynamic response mechanism was firstly observed under an applied magnetic field. Changing magnetic configurations induce the rearrangement of magnetic flux distribution, providing the internal magnetic feedback. Above-mentioned dielectric and magnetic properties of Fe3O4-Fe3O4@C composites make a breakthrough understanding toward the energy conversion mechanisms. (C) 2020 Published by Elsevier Ltd.

Automated summary

Efficient modulation of surface magnetic configurations and electromagnetic responses can be achieved by controlling the growth of magnetic materials. The in situ orientation growth strategy developed here for Fe3O4-Fe3O4@C heterojunctions has demonstrated excellent energy conversion capacity towards electromagnetic waves. The magnetic-dielectric microspheres exhibit strong reflection loss and ultra-wide absorption region, contributing to the understanding of energy conversion mechanisms.