Citation: Liangsen Zhu, Caiyun Cui, Tao Jing, Shihao Tan, Xianguo Liu, Menglin Yu. Strong and broadband microwave absorption under thin thickness induced by multiple dielectric relaxation and multiple magnetic resonances through the dual nanocrystalline phases in amorphous FeSiBCr flakes[J]. Acta Physico-Chimica Sinica, ;2026, 42(9): 100331. doi: 10.1016/j.actphy.2026.100331 shu

Strong and broadband microwave absorption under thin thickness induced by multiple dielectric relaxation and multiple magnetic resonances through the dual nanocrystalline phases in amorphous FeSiBCr flakes

  • Balancing impedance matching and loss capability in amorphous materials remains a huge challenge for obtaining excellent microwave absorption performance. In this work, FeNi and α-Fe dual nanocrystalline phases have been constructed in FeSiBCr flakes to enhance loss capability and optimize impedance matching. Dual ultrafine nanocrystalline phases and amorphous flakes not only provide multiple magnetic loss abilities accompanied by natural resonance, exchange resonance and eddy current loss but also facilitates improved permeability, while introducing rich heterointerfaces between amorphous and nanocrystalline phases brings a large number of defects and dipoles, enhancing multi-polarization losses. Additionally, the amorphous FeSiBCr matrix ensures high resistance and low permittivity. Moreover, ~15 nm amorphous hybrid oxides layer is formed on the surface of FeSiBCr flakes to introduce interfacial polarization. Dual nanocrystalline phases, amorphous FeSiBCr flakes and core-shell structure ensure good impedance matching and enhanced loss capability, leading to remarkable absorption toward microwave. The optimized composites deliver the minimal reflection loss of −40.62 dB at 12.4 GHz under 2.20 mm and the optimal effective absorption bandwidth of 6.40 GHz with 1.90 mm, covering 11.44–17.84 GHz. Furthermore, periodic multilayer structure design can extend absorption bandwidth to 12.68 GHz, with an increase of 198.1%. Radar cross section simulation further supports its good stealth performance in real-world scenarios.
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