Hierarchical triplet-metallic oxide/carbon nanocomposites constructed from 2D layered double hydroxides and metal-organic frameworks for high-performance microwave absorption

In the face of increasingly severe electromagnetic wave radiation and interference, it is of great significance to design and prepare excellent absorbing materials. Particularly, hierarchical structure has emerged with enhanced physicochemical properties, offering enormous potential for designing absorbing materials. Here, a hierarchical structure composite constructed by ZIF-8 and fungus-like nickel-cobalt layered double hydroxide (Ni, Co-LDH) nanosheets were synthesized by in-situ self-assembly growth process. A series of Zn@NiCo-Lc composites were obtained by calcination under air. Calcined derivatives of dielectric and magnetic metallic oxides and carbon give rise to multiple polarizations and magnetic losses. The matching of the dielectric and magnetic losses of the hybrid material is further tuned by varying the feed ratio of the bimetallic LDH nanosheets, resulting in a sample with tunable EMA performance. All samples exhibit comparable EMA performance, especially large EABmax max of above 5.5 GHz, and Zn@NiCo-Lc-2 has the strongest EMA intensity performance ( RL min is-67.61 dB at an ultra- thin thickness of 1.71 mm). This study provides a tractable method for the fabrication of hierarchical structural composites of high-performance MOF/LDH-derived absorbers, further broadening the application and development of novel electromagnetic wave absorption materials.