MOF Derivatives with Gradient Structure Anchored on Carbon Foam for High‐Performance Electromagnetic Wave Absorption

The impedance matching and high loss capabilities of composites with homogeneous distribution are limited owing to high addition and lack of structural design. Developing composites with heterogeneous distribution can achieve strong and wide electromagnetic (EM) wave absorption. However, challenges such as complex design and unclear absorption mechanisms still exist. Herein, a novel composite with a heterogeneous distribution gradient is successfully constructed via MOF derivatives Co@ nitrogen‐doped carbon (Co@NC) anchored on carbon foam (CF) matrix (MDCF). Notably, the concentration of MOF can easily control the gradient structure. In particular, the morphologies of MOF derivatives on the surface of CF undergo a transition from the collapse of the inner layer to the integrity of the outer layer, accompanied by a continuous reduction in the size of Co nanoparticles. Correspondingly, enhanced interface polarization from the core‐shell of Co@NC and good impedance matching of MDCF can be obtained. The optimized MDCF exhibits the minimum reflection loss of −68.18 dB at 2.01 mm and effective absorption bandwidth covering the entire X‐band. Moreover, MDCF exhibits lightweight characteristics, excellent compressive strength, and low radar cross‐section reduction. This work highlights the immense potential of composites with heterogeneous distribution for achieving high‐performance EM wave absorption. A gradient composite via MOF derivatives anchored on carbon foam matrix (MDCF) is prepared, and the micro‐mechanism is thoroughly investigated to illustrate the importance of structural design in EM wave absorption. This study guides composite with gradient structure for achieving high‐performance EM wave absorption and yields a novel insight into cooperate impedance matching and attenuation capability.