A Novel Strategy in Electromagnetic Wave Absorbing and Shielding Materials Design: Multi-Responsive Field Effect

The electromagnetic (EM) devices have been widely used in communication, electrical engineering, and medical care. However, EM device is a double-edged sword for its convenience is followed by signal pollution and radiation. Electromagnetic interference (EMI) combat has brought lots of attention to researchers in this field. Researchers have made great efforts in developing electromagnetic wave absorbing and shielding (EMAS) materials to reduce EM wave power density to solve the above problem. However, the great majority of reported EMAS materials are powders and coatings, which possess merely EMAS property. Modern practical application has abundant multiple scenes, including high temperature, intense light, water flow, etc. Under the circumstances, EMAS materials should be functionalized with outstanding tunable absorption bands. Based on field theory in physics, multiexternal fields-responsive materials are an effective method to deal with the above urgently unsolved problem. Thus, herein, different external field-responsive materials, including temperature, light, space-time, electrical, wind, density, and flow fields, are focused on. Various action mechanisms, materials synthesis methods, and different macrostructures are summarized in detail. Meanwhile, the developing trends of novel external field-responsive materials are also discussed in order. Finally, the challenges of designing new type of EMAS devices are mentioned.

Automated summary

The use of electromagnetic (EM) devices has become widespread in various fields, but it also brings about issues such as signal pollution and radiation. To tackle these problems, researchers have been working on developing electromagnetic wave absorbing and shielding (EMAS) materials. However, most of the reported materials only possess the EMAS property. In practical applications, materials with excellent tunable absorption bands are needed. This review focuses on different external field-responsive materials and provides a detailed summary of various action mechanisms, materials synthesis methods, and macrostructures. The future trends in developing novel external field-responsive materials are also discussed.