Quadrangular cone carbon-constructed effective 3D network for a lightweight and broadband microwave absorbent.

Three-dimensional carbon-based materials have attracted much attention for electromagnetic wave absorption because low-dimensional materials have failed to meet the needs of constructing effective networks with ultra-light properties due to their easy agglomeration and in-plane stacking. The 3D element of quadrangular cone carbon was innovatively applied in this work to construct interconnected networks (MFC). This material successfully overcomes the disadvantages of easy agglomeration and in-plane stacking in low-dimensional elements, allowing for more efficient construction of absorbing networks.

Checkerboard-like nickel nanoislands/defect graphene aerogel with enhanced surface plasmon resonance for superior microwave absorption.

To solve the problem of dispersion of magnetic nanoparticles in ultralight electromagnetic absorption field, checkerboard-like nickel nanoislands/defect graphene aerogel (NIDG) with enhanced surface plasmon resonance was designed and prepared through electrostatic self-assembly method. This special structure successfully overcame the aggregation phenomenon of magnetic metals and built high-density gap regions to enhance surface plasmon resonance. And the NIDG has achieved excellent electromagnetic wave absorption performance in C band.

High aspect-ratio sycamore biomass microtube constructed permittivity adjustable ultralight microwave absorbent.

Excessive conductivity of carbon-based materials led to poor impedance matching, hindering their electromagnetic absorbing application in aerospace and military fields. While, one-dimensional carbon materials are more favorable to build networks, satisfying impedance matching. One-dimensional carbon materials, such as carbon fibers, carbon nanotubes, carbon microtubes, etc.