Heterointerface engineering of Cr2AlC@SiO2 composites for synergistically enhanced microwave absorption and high-temperature oxidation resistance

Background

To meet the demand for electromagnetic stealth and reliable service in high-temperature components, developing materials integrating excellent microwave absorption performance (MAP) with high-temperature stability is crucial. Heterointerface engineering serves as a significant approach for enhancing such materials.

Methods

Herein, core-shell structured Cr₂AlC@SiO₂ composites were constructed via the Stöber process, showing enhanced high-temperature durability and electromagnetic wave attenuation capabilities. The introduced SiO₂ coating elevated the oxidation onset temperature of Cr₂AlC by 30.8 % and reduced the high-temperature oxidation activation energy (E_a) by up to 48.4 % by suppressing substrate E_a and reducing the oxygen-exposed surface area. At a thickness of 2.0 mm, the Cr₂AlC@SiO₂ composite exhibited superior MAP with a minimum reflection loss (RL_min) of -15.11 dB and an effective absorption bandwidth (EAB, RL < -10 dB) of 2.73 GHz. Compared with pristine Cr₂AlC, these values represent a 23.0 % reduction in RL_min and a 99.3 % expansion in EAB.

Significant findings

The performance improvement stems primarily from the synergistic effects of dielectric-regulated impedance matching mediated by the SiO₂ layer, coupled with the heterointerface establishing a multi-scale scattering network that collectively enhances electromagnetic energy dissipation. This research provides a novel design paradigm for developing advanced microwave absorbers integrating exceptional thermal stability and broadband absorption performance.