Abstract

High-entropy MXenes, as a new emerging class of materials, possess diverse compositions, unexpected physicochemical characteristics and great potentials for electromagnetic (EM) wave absorption. Herein, two single-to-few-layer high-entropy MXenes, (Mo_0.25Cr_0.25Ti_0.25V_0.25)₃C₂T_x and (Mo_0.2Cr_0.2Nb_0.2Ti_0.2V_0.2)₄C₃T_x, were synthesized for the first time. During the exfoliation and delamination processes, the structural, morphological and compositional evolutions were analyzed, verifying the successful formation of single-to-few-layer two-dimensional MXene nanosheets. Investigations indicate that with the filling content of only 35 wt%, MXene powders filled composites exhibit high-efficiency EM wave absorption performances. The f-(Mo_0.25Cr_0.25Ti_0.25V_0.25)₃C₂T_x possesses the minimum reflection loss (RL_min) of -45.0 dB with the matching thickness of 1.52 mm and the maximum effective absorption bandwidth (EAB) of 5.6 GHz at 1.65 mm thickness. Also, f-(Mo_0.2Cr_0.2Nb_0.2Ti_0.2V_0.2)₄C₃T_x can attain a RL_min of -52.8 dB with the thickness of 1.58 mm and an optimum EAB value of 3.6 GHz at 1.50 mm. The satisfactory EM wave absorption efficiency and bandwidth, thin matching thickness and low filling content prove the lightweight advantage and great application potential of high-entropy MXenes in EM wave absorption. In this work, the high-entropy strategy is applied to tune the EM wave absorption performances for MXenes. Furthermore, high-entropy engineering is expected to provide control and tunability of many other properties, such as electrochemical, catalytic, and mechanical behaviors.