Litcius/Paper detail

Morphology-Evolved Succulent-like FeCo Microarchitectures with Magnetic Configuration Regulation for Enhanced Microwave Absorption

Ziqi Yang, Wenbin You, Xuhui Xiong, Ruixuan Zhang, Zhengchen Wu, Biao Zhao, Min Wang, Xianhu Liu, Xuefeng Zhang, Renchao Che

2022ACS Applied Materials & Interfaces37 citationsDOI

Abstract

The regulation of magnetic configuration through diverse morphologies to achieve a rapid magnetic response has attracted considerable academic favor on account of the unique application prospects in various fields. Herein, porous FeCo alloys with morphology evolved from spheres to succulent-like microstructures are successfully constructed via a facile hydrothermal reaction–hydrogen reduction synthetic strategy. A multiple balance/competition mechanism is proposed, including the coexistence of the dissolution–precipitation balance of hydroxides and the dissociation–stability balance of coordination compounds, the Fe3+–Co2+ competition, and the precipitation–coordination reaction contest. As the morphology evolves to a succulent-like assembly, the multidomain features with a stable combination of vortex states and the violent motion of magnetic vectors contribute to the improvement of magnetic storage capacity and loss capability, which are evidenced by the off-axis electron holography and micromagnetic simulation. Consequently, the succulent-like FeCo exhibits enhanced permeability and microwave absorption performance. The effective absorption bandwidth reaches 5.68 GHz, and the maximum reflection loss is elevated to −53.81 dB. This work sheds considerable insight into the microstructure regulation with an application in microwave absorption and offers guidance in research for the topological magnetic configuration and dynamic response mechanism of magnetic alloys.

Topics & Concepts

Materials scienceMicrowaveMicrostructureReflection lossChemical physicsPermeability (electromagnetism)Absorption (acoustics)NanotechnologyChemical engineeringCondensed matter physicsOptoelectronicsComposite materialEngineeringGeneticsComposite numberBiologyQuantum mechanicsPhysicsMembraneElectromagnetic wave absorption materialsAdvanced Antenna and Metasurface TechnologiesMetamaterials and Metasurfaces Applications