Oxygen vacancy boosted microwave absorption in CeO2 hollow nanospheres

Oxygen vacancy engineering is one of the key strategies to modulate the electric structure and properties of metal oxides. However, the relationship between oxygen vacancies and electromagnetic wave (EMW) absorption capabilities is so far unclear. Herein, oxygen vacancy boosted microwave absorption was realized over CeO2 dual-shell hollow nanospheres (HNSs), which can be tuned by thermal conversion temperatures (T-s) of CeOHCO3 HNSs. The lattice stress decreases linearly, and the conductivity increases gradually with the elevating T-s. Our findings show that a moderate T-s favors the formation of dual-shell CeO2 HNSs with a high oxygen vacancy concentration, a large S-BET, an appropriate lattice defect, and proper conductivity. The abundant oxygen vacancies endow CeO2 HNSs with massive localized electrons and dipole centers, which benefit the conductivity, conductive loss, defect/dipole polarizations. CeO2 DSHNSs formed at T-s = 400 ? bear broad bandwidth (5.44 GHz) and strong absorption (-43.28 dB), far superior to the reported CeOHCO3 single-shell HNSs, CeO2 single-shell HNSs, and most other CeO2-based composites. Overall, this work establishes a clear correlation between oxygen vacancy defects and EMW dissipation ability, offering valuable insights for designing superior EMW absorbents.

Automated summary

This study demonstrates that oxygen vacancy engineering can modulate the electric structure and properties of metal oxides to enhance microwave absorption. By tuning the thermal conversion temperatures, dual-shell CeO2 nanospheres with high oxygen vacancy concentration and proper conductivity can achieve superior microwave absorption capabilities.