Tunable microwave absorption features in bi-layer absorber based on mesoporous CuS micro-particle with 3D hierarchical structure and nanosphere like NiCo2O4

There has been a growing demand for materials with superior absorption capabilities, such as strong absorbing capacity, thin thickness, and light weight, to solve challenges related to EM radiation pollution. While the majority of the research is focused on optimizing material compositions, component microstructure and absorber structure are also critical factors for improving microwave absorption performance. In this research, we show how the microstructure of components and absorber design may increase dissipation features. Solvothermal and hydrothermal methods were utilized for synthesizing mesoporous CuS micro-particles with a 3D hierarchical structure as a dielectric component and nanospheres like NiCo2O4 as magnetic components respectively. The formation of pure phases with the mentioned microstructures was confirmed via XRD, FTIR, UV-Vis, XPS, VSM, FESEM and BET analysis. According to VNA results, the minimum reflection loss can be achieved to -33 dB at 11 GHz with a total thickness of 2 mm in which each layer thickness was considered 1 mm (CuS placed at top layer and NiCo2O4 placed at bottom layer). The RL values of bilayer absorber were strongly affected by both the microstructure of the components and tuning the thickness and arrangement of each layer. We offer a potential technique for enhancing microwave dissipation performance by combining the synergistic effects between the microstructure, thickness and arrangement of layers in a bilayer absorber.

Automated summary

This research demonstrates the potential of enhancing microwave absorption performance by adjusting the microstructure and absorber design. By synthesizing hierarchical CuS and spherical NiCo2O4 particles, the researchers achieved the minimum reflection loss values at specific thickness and arrangement.