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W4285494706 abstract "Rapid recombination of photoinduced charge carriers is one of the most significant problems for promoting the photocatalytic efficiency of photocatalysts. The photocatalytic reaction efficiency is restrained by the intrinsic slow separation but the rapid recombination of light-induced carriers, thus performing unsatisfactorily. The light-induced electrons and holes must have adequate lifetimes to transfer to the active centers where chemical reactions occur instead of recombining to generate photoluminescence irradiation or heat. In our work, based on the Lorentz force-driven enhanced separation of electrons and holes in BiOBr (BOB), further improvement of the charge carriers transfer was achieved by introducing boron nitride quantum dots (BNQDs) to BOB with a permanent magnet. The photodegradation efficiency of BOB with a magnetic field improved by 41% compared to results without a magnetic field, and the further enhancement of BOB/BNQDs with the Lorentz force was enhanced by 21%. This new strategy combined separation of photoinduced charge carrier via Lorentz force and hole transfer by BNQDs to improve photocatalytic efficiency. Furthermore, sufficient active sites were introduced into BOB/BNQDs because of the quantum dots, which also improved photocatalytic redox reaction efficiency. This work provided a novel sight of combining Lorentz force and quantum dots without energy consumption to solve the rapid recombination problem." @default.
W4285494706 created "2022-07-15" @default.
W4285494706 creator A5034762118 @default.
W4285494706 creator A5041151661 @default.
W4285494706 creator A5078655199 @default.
W4285494706 date "2022-07-14" @default.
W4285494706 modified "2023-10-06" @default.
W4285494706 title "Boosting Separation of Charge Carriers in 2D/0D BiOBr Nanoflower Sheets/BN Quantum Dots with the Lorentz Force via Magnetic Field" @default.
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W4285494706 doi "https://doi.org/10.1021/acs.energyfuels.2c01364" @default.
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