Electromagnetic Wave Absorption Performance of FeCoCrAl0.4Vx High-Entropy Alloys by Adjusting the Amount of V Content

doi:10.1007/s40195-025-01918-x

Abstract

Abstract:

High-entropy alloys (HEAs) show excellent prospects in microwave absorbing materials due to their designable composition and variable electromagnetic properties. In this work, FeCoCrAl_0.4V_x HEAs with body-centered cubic (BCC) single-phase solid solution structure were prepared by mechanical alloying and heat treatment. By varying the content of vanadium (V), the grain size, lattice constant, crystallinity, particle size, and microscopic morphology can be effectively adjusted, thereby enabling the optimization of their electromagnetic properties and microwave absorption performance. Doping a small amount of V element can refine the BCC grains, regulate the particle size, and enhance the electrical conductivity, which significantly improves the polarization relaxation, conduction loss, and eddy current loss of HEAs. In addition, the increased crystallinity and reduced lattice defects can enhance natural resonance loss at a high frequency (GHz), which will contribute to the improvement of impedance matching and electromagnetic attenuation. The annealed FeCoCrAl_0.4V_0.2 HEAs exhibit excellent wave absorption properties, achieving a maximum reflection loss of −44.3 dB at 1.8 mm thickness and an effective absorption bandwidth of 4.0 GHz at 1.2 mm, respectively. This study provides a new strategy for developing lightweight and high-performance high-entropy alloys microwave absorbing materials.

Key words: High-entropy alloys, Microwave absorbing materials, Refine grains, Impedance matching

Liang Liang, Huifang Pang, Renguo Guan, Wenbo Du, Minqiang Gao, Jin Zhang, Huan Ma. Electromagnetic Wave Absorption Performance of FeCoCrAl_0.4V_x High-Entropy Alloys by Adjusting the Amount of V Content[J]. Acta Metallurgica Sinica (English Letters), 2025, 38(12): 2217-2227.

Figures/Tables 9

Fig. 1 HEAs preparation process diagram

Fig. 2 a XRD phase patterns, b calculated lattice constant and grain size, c particle size of annealed HEAs with different V content, d, e, g, h SEM images of annealed HEAs, f TEM images of A0.2 HEAs, i HRTEM image and SAED pattern for A0.2 HEAs, j distribution diagram of each element of A0.2 HEAs

Fig. 3 a Hysteresis loop of annealed FeCoCrAl0.4Vx (x = 0, 0.1, 0.2, 0.3, 0.4, 0.5), b local enlarged image of a, c Ms and Hc trend, d electrical conductivity

Fig. 4 Electromagnetic properties of annealed FeCoCrAl0.4Vx HEAs: a real permittivity, b imaginary permittivity, c dielectric loss tangent, d real permeability, e imaginary permeability, f magnetic loss tangent

Fig. 5 EMW absorption properties of annealed FeCoCrAl0.4Vx HEAs: a A0, b A0.1, c A0.2, d A0.3, e A0.4, f A0.5

Fig. 6 a-f Cole-Cole curves of annealed FeCoCrAl0.4Vx (x = 0, 0.1, 0.2, 0.3, 0.4, 0.5) HEAs

Fig. 7 a Modulus of the normalized impedance Zr, b Attenuation constant

Fig. 8 Performance comparison chart of absorbing materials

Fig. 9 Electromagnetic wave absorption mechanism diagram

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