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Article Abstract
Graphdiyne (GDY), an emerging member in the carbon material family, possesses abundant chemical bonds, extended conjugated systems, and superior charge carrier mobility, establishing it as a promising novel microwave absorption material. Capitalizing on these attributes, in this work, a flower-like GDY@CuO composite with a unique nanowall structure is prepared by a one-step microemulsion method. Remarkably, temperature-mediated enhancement of electron transport coupled with induced multipolarization synergistically boosts the microwave absorption performance. The optimal specimen (GDY@CuO-700) achieves an effective absorption bandwidth (EAB) of 6.1 GHz at 2.2 mm matched thickness, with a minimum reflection loss of -49.9 dB@17.7 GHz. Furthermore, a metamaterial is designed at the millimeter scale using GDY@CuO-700 as the microwave absorbing functional component. Following optimization via 3D electromagnetic simulation software, this metamaterial demonstrates an ultra-broad EAB spanning 34.1 GHz in the range of 2-40 GHz. This pioneering study delineates the electromagnetic wave absorption characteristics of GDY-based microspheres with GDY as the primary constituent and provides a valuable reference for designing innovative wave-absorbing materials.
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