Understanding the efficient microwave absorption for FeCo@ZnO flakes at elevated temperatures a combined experimental and theoretical approach

doi:10.1016/j.jmst.2021.12.079

Abstract

Abstract:

Considerable microwave absorption performance at elevated temperatures is highly demanded in both civil and military fields. Single dielectric or magnetic absorbers are difficult to attain efficient and broadband microwave absorption at the high temperature range of 373 K-573 K, and the evolution mechanism of the microwave absorption is still unclear especially for the magnetic absorbers. Herein, ZnO coated flaky-FeCo composite is proposed to break through the bottleneck, which possesses microwave absorption (RL<-10 dB) that covering the whole X band (8.2 GHz-12.4 GHz) at the temperature range of 298 K-573 K with a thickness of only ∼2 mm. Moreover, attenuation mechanism and evolution of the microwave absorption properties for the FeCo@ZnO flaky material at elevated temperature has been clearly disclosed by the composition and microstructure characterizations, electromagnetic performance measurements and first principles calculations for the first time. Moreover, the Poynting vector, volume loss density, magnetic field (H) and electric field (E) are simulated by HFSS to understand the interaction between EM waves and the samples at different temperatures, further elaborating the attenuation mechanism in high-temperature environment. This study provides guidance in designing and developing high-temperature microwave absorbers for the next generation.

Key words: ZnO coated flaky-FeCo, High-temperature microwave absorption, First principles calculation, HFSS simulation

Kangsen Peng, Chuyang Liu, Yuhan Wu, Gang Fang, Guoyue Xu, Yujing Zhang, Chen Wu, Mi Yan. Understanding the efficient microwave absorption for FeCo@ZnO flakes at elevated temperatures a combined experimental and theoretical approach[J]. J. Mater. Sci. Technol., 2022, 125: 212-221.

Figures/Tables 8

Fig. 1. A series experimental test at different temperatures. (a) XRD patterns with calculated curves and (b) the statistics for lattice parameters and quality ratio of ZnO and FeCo, (c) the Raman spectrum of FeCo@ZnO, XPS spectra of (d) Fe and (e) O, (f) the statistics of O ratio and Ion-Fe ratio.

Fig. 2. SEM images of (a) ZnO and FeCo, (b) ZnO coated FeCo with enlarged mapping area. (c) The element mapping of FeCo@ZnO. (d) The TEM images, (e) the HRTEM image of area I with corresponding SAED patterns and (f) FFT patterns with inverse FFT, (g) the enlarged view of area II and (h) area III with (i) FFT patterns and inverse FFT images.

Fig. 3. (a) 2D counter map of RL and (b) 2D curve of RL in different thickness at 298 K-573 K temperature range.

Fig. 4. (a) The frequency dependence of complex permeability and permittivity, (b) the band structure and (c) the DOS curves of ZnO phase at 298 K-573 K temperature range.

Fig. 5. The frequency dependence of (a) impedance matching, (b) attenuation constant, (c) dielectric loss tangent and (d) magnetic loss tangent. The HFSS simulation results of (e) Poynting vectors and (f) volume loss density at different temperatures.

Fig. 6. The HFSS simulation results for (a) intensity of electric field and (b) intensity of magnetic field at 298 K-573 K temperature range.

Fig. 7. Schematic illustration of (a) the microwave absorption mechanisms and (b) the intrinsic variation mechanism of complex electromagnetic parameters and microwave absorbing performance at increasing temperatures.

Table 1. Comparison between the vast majority of the current absorbers at elevated temperatures.

Sample	RL_min(dB)	EAB(GHz)	Thickness(mm)	Temperature(K)	Refs.
FeCo@ZnO	31.1	4.2	1.85	373	This work
FeCo@ZnO	-22.8	3.3	1.85	573	This work
SiC-NiO	Unclear	1.9	Unclear	373	[8]
SiC-NiO	Unclear	2.5	Unclear	573	[8]
Co₃O₄@rGO/SiO₂	-23	4.0	2	393	[10]
Co₃O₄@rGO/SiO₂	-18	3.4	2	473	[10]
CdS-MWCNTs	-25	4.2	2.5	373	[43]
CdS-MWCNTs	-14	3.3	2.5	573	[43]
TiC/SiO₂	-27	2.6	2.5	373	[46]
TiC/SiO₂	-22	2.8	2.5	573	[46]

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