Nano metal oxide-intercalated MXene in-situ prepared by irradiation as effective electromagnetic wave absorbents

With the rapid development of electronic communication technology, electromagnetic pollution has become increasingly severe, leading to a growing need for absorption materials with excellent absorption performance. Herein, nano-sized oxide-intercalated Ti3C2T (x) MXene composites were synthesized via ?-radiation in an aqueous system. The synthesis was conducted in a reducing environment at room temperature, which effectively prevented the oxidation of MXene. Nano-oxides (Fe2O3 and Cu2O) were formed in situ between the MXene layers, forming a homogeneous oxide-intercalated structure. Compared with the original MXene, the intercalated structure significantly enhanced the electromagnetic wave absorption (EMA) performance of the MXene/Fe2O3 composite in the frequency range of 2-18 GHz, with smaller reflection loss (RL) (-58.7 dB), thinner thickness (2.35 mm). The RLmin value of the MXene/Cu2O composite was -50.9 dB (2.55 mm) and the effective frequency width was 4.88 GHz at a thickness of 1.3 mm. Compared with ordinary chemical methods, the ?-radiation is a facile and 'green' method that is suitable for large-scale preparation. The absorption mechanism was attributed to conductive loss, polarization loss, and magnetic loss, which contributed to efficient EMA. This work demonstrates that ?-radiation is a promising method for preparing nano metal oxide-intercalated MXene with enhanced EMA performance.

Automated summary

Nano-sized oxide-intercalated MXene composites were synthesized via ?-radiation, which significantly enhanced their electromagnetic wave absorption performance. The composites showed smaller reflection loss and thinner thickness in the frequency range of 2-18 GHz. This work demonstrates that ?-radiation is a promising method for preparing nano metal oxide-intercalated MXene with enhanced EMA performance.