Hollow porous Fe 2O 3 microspheres wrapped by thin RGO sheets exhibited high-performance microwave absorption with a reflection loss value of −48.1 dB and an effective absorption bandwidth cover of 5.28 GHz.
Benefiting from the assistance of an organic ligand, porous Fe 2O 3 microspheres tightly wrapped by reduced graphene oxides (Fe 2O 3@RGO) were synthesized via a facile one-step hydrothermal method. The assembled Fe 2O 3 microspheres with different morphologies and sizes can be effectively regulated by controlling the addition of the iron source. The as-synthesized Fe 2O 3 spheres gradually changed from solid, hollow to a final solid ball with decreasing sizes from 800 nm to 200 nm. Intrinsic dielectric properties and charge density distribution were characterized by vector network analysis (VNA) and off-axis electron holography. Owing to their unique structure design, better electron transport behavior and enhanced dielectric and interfacial polarization, RGO wrapped hollow Fe 2O 3 microspheres exhibit the best electromagnetic energy conversion ability. The maximum reflection loss can reach −48.1 dB and the effective absorption bandwidth cover is 5.28 GHz (10.48–15.76 GHz) at 2.5 mm. Tuning the thickness from 1 to 5 nm, the strongest reflection loss peaks can shift from high to low frequency, showing adjusting absorption properties.