Cationic hybridization produces core-shell structure MOF derivatives for reducing electromagnetic pollution

Microstructure design and genetic modification with metal-organic frameworks is one of the key strategies for combating electromagnetic pollution, albeit it continues to face constraints. Since inappropriate parameter selection during microstructure modification is extremely likely to result in pore collapse, metal agglomeration and other issues. Herein, we propose an efficient cation hybridization strategy where we etch the precursor MIL-53 by different etching concentrations and anneal it at various temperatures. Ultimately, light and efficient MOFsderived microwave absorption materials are obtained. Notably, the magnetic heterogeneous atoms introduced by the cationic hybridization reaction not only provide perfect heterogeneous interfaces but improve the electromagnetic synergistic effect. Benefiting from the optimized impedance matching provided by electric-magnetic synergistic loss mechanism and the polarization effect generated by a large number of heterogeneous interfaces and defects, the MD-2 has shown ultra-high electromagnetic parameters and excellent microwave absorption performance with a qualified absorption bandwidth of 6.97 GHz (2.36 mm) and a minimum reflection loss of -75.61 dB. In addition to broadening the permittivity-magnetic synergistic mechanism of microwave absorption materials under the morphology-property relationship, the general approach inspired by this strategy also lays a solid foundation for the EMW absorption of artificial intelligence microdevices in the 5G era.

Automated summary

Microstructure design and genetic modification with metal-organic frameworks is a key strategy for combating electromagnetic pollution. By optimizing the cation hybridization reaction and introducing magnetic impurities, light and efficient microwave absorption materials with improved electromagnetic synergistic effect can be obtained.