Enabling highly efficient and broadband electromagnetic wave absorption by tuning impedance match in high-entropy transition metal diborides (HE TMB2)

Weiming Zhang,Fu-Zhi Dai,Na Ni,Rajamallu Karre,Shijiang Wu,Yanchun Zhou,Biao Zhao,Xiaohui Wang,Huimin Xiang

doi:10.1007/s40145-021-0505-y

Abstract

The advance in communication technology has triggered worldwide concern on electromagnetic wave pollution. To cope with this challenge, exploring high-performance electromagnetic (EM) wave absorbing materials with dielectric and magnetic losses coupling is urgently required. Of the EM wave absorbers, transition metal diborides (TMB2) possess excellent dielectric loss capability. However, akin to other single dielectric materials, poor impedance match leads to inferior performance. High-entropy engineering is expected to be effective in tailoring the balance between dielectric and magnetic losses through compositional design. Herein, three HE TMB2 powders with nominal equimolar TM including HE TMB2-1 (TM = Zr, Hf, Nb, Ta), HE TMB2-2 (TM = Ti, Zr, Hf, Nb, Ta), and HE TMB2-3 (TM = Cr, Zr, Hf, Nb, Ta) have been designed and prepared by one-step boro/carbothermal reduction. As a result of synergistic effects of strong attenuation capability and impedance match, HE TMB2-1 shows much improved performance with the optimal minimum reflection loss (RLmin) of −59.6 dB (8.48 GHz, 2.68 mm) and effective absorption bandwidth (EAB) of 7.6 GHz (2.3 mm). Most impressively, incorporating Cr in HE TMB2-3 greatly improves the impedance match over 1–18 GHz, thus achieving the RLmin of −56.2 dB (8.48 GHz, 2.63 mm) and the EAB of 11.0 GHz (2.2 mm), which is superior to most other EM wave absorbing materials. This work reveals that constructing high-entropy compounds, especially by incorporating magnetic elements, is effectual in tailoring the impedance match for highly conductive compounds, i.e., tuning electrical conductivity and boosting magnetic loss to realize highly efficient and broadband EM wave absorption with dielectric and magnetic coupling in single-phase materials.

Highlights

The ubiquitous electromagnetic (EM) wave pollutions accompanying the massive usage of wireless communication technologies have evolved into worldwide threats, which have harmful impacts on biological health and normal operation of electronic devices [1,2,3]
Dielectric loss-type absorbers include carbon fiber (CF) [6], carbon nanotube (CNT) [7], reduced graphene oxide [8], conductive polymer [9], oxides, transition metal sulfides [12], silicon carbide [13], and 2D transition metal carbides/ nitrides/carbonitrides (MXenes) [14], and magnetic loss-type absorbers consist of ferrites [15,16,17] and magnetic metals [18,19,20]
Theoretical calculations based on density functional theory (DFT) reveal that TiB2 possesses the highest degree of ionicity, and CrB2 exhibits partially polarized spin, while d-orbital splitting effects are commonly observed among TMB2s

Summary

Introduction

The ubiquitous electromagnetic (EM) wave pollutions accompanying the massive usage of wireless communication technologies have evolved into worldwide threats, which have harmful impacts on biological health and normal operation of electronic devices [1,2,3] To tackle this hazard, EM wave absorbing materials that are capable of converting EM energy into thermal energy or other forms of energy have drawn considerable attentions [4,5]. It is significant to realize dielectric and magnetic losses coupling in single-phase materials that possess highly efficient EM wave absorption performance, easy processability, good thermal stability, and good resistance to oxidation and corrosion

Methods

Results

Conclusion