Achieving electromagnetic wave absorption capabilities by fabrication of flower-like structure NiCo2O4 derived from low-temperature co-precipitation

In this work, The NiCo2O4 with 3D hierarchical multilayer flower-like structure was prepared by the lowtemperature (55 degrees C) co-precipitation method combined with the calcination process, avoiding the traditional high-temperature hydrothermal synthesis method. The prepared flower-like NiCo2O4 with a large specific surface area was characterized by X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), scanning electron microscopy (SEM) and automatic surface area and porosity analyzer (BET) and vector network analyzer (VNA). A novel evaluation approach was proposed to evaluate the electromagnetic wave (EMW) absorbing properties of various samples (different calcination temperatures), which was to defined the Delta S as the area enclosed by the curve when the reflection loss (RL) value was less than -10. In order to take the material thickness into account, and then the effective reflection loss (RLE) value was defined Delta S/d to measure the electromagnetic wave (EMW) loss capability of the different samples. The results showed that NiCo2O4 exhibited excellent EMW absorption effect when the calcination temperature was 400 degrees C, and the maximum RL value reached -43.17 dB at 14.32 GHz with the thickness of 1.5 mm and the effective absorption bandwidth (fe) was 4.48 GHz (12.08 GHz-16.56 GHz). The excellent EMW absorption property was mainly due to NiCo2O4 with particular porous flower-like structure, which could achieve impedance matching to loss EMW by dielectric loss and magnetic loss.

Automated summary

In this study, a 3D hierarchical multilayer flower-like NiCo2O4 structure was successfully prepared using a low-temperature co-precipitation method and calcination process. The NiCo2O4 exhibited excellent electromagnetic wave absorption properties, attributed to its unique porous flower-like structure that achieved impedance matching to loss electromagnetic waves.