Internal electric fields drive dual S-scheme heterojunctions: Insights into the role of the triple interlaced lattice

[Display omitted] •The dual S-scheme Bi2O2CO3/Bi2WO6/C3N4 heterojunction with interlaced lattice was constructed.•Efficient removal of ciprofloxacin was achieved in Bi2O2CO3/Bi2WO6/C3N4 heterojunction.•The fully blossomed flower-like structure promoted light harvesting and charge transfer.•The role...

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Veröffentlicht in:Journal of colloid and interface science 2023-11, Vol.650 (Pt B), p.1138-1151
Hauptverfasser: Zhou, Zhanpeng, Zeng, Hao, Li, Ling, Tang, Rongdi, Xiong, Sheng, Gong, Daoxin, Huang, Ying, Deng, Yaocheng
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container_end_page 1151
container_issue Pt B
container_start_page 1138
container_title Journal of colloid and interface science
container_volume 650
creator Zhou, Zhanpeng
Zeng, Hao
Li, Ling
Tang, Rongdi
Xiong, Sheng
Gong, Daoxin
Huang, Ying
Deng, Yaocheng
description [Display omitted] •The dual S-scheme Bi2O2CO3/Bi2WO6/C3N4 heterojunction with interlaced lattice was constructed.•Efficient removal of ciprofloxacin was achieved in Bi2O2CO3/Bi2WO6/C3N4 heterojunction.•The fully blossomed flower-like structure promoted light harvesting and charge transfer.•The role of the interlaced lattice interface in the charge transfer mechanism was revealed. The internal electric field induced by the lattice interfaces in a heterojunction can facilitate charge transfer, thereby improving the photocatalytic performance. However, the details of the relationship between the lattice interfaces and the charge transfer mechanism in heterojunctions remain unclear. In this study, a Bi2WO6/Bi2O2CO3/C3N4 heterojunction (BBC) with an interlaced lattice was prepared, and the role of the interlaced lattice in charge transfer was revealed. Compared to pristine Bi2O2CO3, Bi2WO6, and C3N4, BBC exhibited an increased ciprofloxacin degradation rate constant (0.0573 min−1). A series of experiments were performed to reveal the role of the interlaced lattice interface in the enhanced photocatalytic performance. The results show that the driving force provided by the interlaced lattice interface changes the charge transfer mechanism from a dual Ⅱ-scheme to a dual S-scheme. This work provides profound insights into the effects of lattice interfaces in heterojunctions and the design of efficient photocatalysts.
doi_str_mv 10.1016/j.jcis.2023.07.086
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The internal electric field induced by the lattice interfaces in a heterojunction can facilitate charge transfer, thereby improving the photocatalytic performance. However, the details of the relationship between the lattice interfaces and the charge transfer mechanism in heterojunctions remain unclear. In this study, a Bi2WO6/Bi2O2CO3/C3N4 heterojunction (BBC) with an interlaced lattice was prepared, and the role of the interlaced lattice in charge transfer was revealed. Compared to pristine Bi2O2CO3, Bi2WO6, and C3N4, BBC exhibited an increased ciprofloxacin degradation rate constant (0.0573 min−1). A series of experiments were performed to reveal the role of the interlaced lattice interface in the enhanced photocatalytic performance. The results show that the driving force provided by the interlaced lattice interface changes the charge transfer mechanism from a dual Ⅱ-scheme to a dual S-scheme. 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The internal electric field induced by the lattice interfaces in a heterojunction can facilitate charge transfer, thereby improving the photocatalytic performance. However, the details of the relationship between the lattice interfaces and the charge transfer mechanism in heterojunctions remain unclear. In this study, a Bi2WO6/Bi2O2CO3/C3N4 heterojunction (BBC) with an interlaced lattice was prepared, and the role of the interlaced lattice in charge transfer was revealed. Compared to pristine Bi2O2CO3, Bi2WO6, and C3N4, BBC exhibited an increased ciprofloxacin degradation rate constant (0.0573 min−1). A series of experiments were performed to reveal the role of the interlaced lattice interface in the enhanced photocatalytic performance. The results show that the driving force provided by the interlaced lattice interface changes the charge transfer mechanism from a dual Ⅱ-scheme to a dual S-scheme. 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The internal electric field induced by the lattice interfaces in a heterojunction can facilitate charge transfer, thereby improving the photocatalytic performance. However, the details of the relationship between the lattice interfaces and the charge transfer mechanism in heterojunctions remain unclear. In this study, a Bi2WO6/Bi2O2CO3/C3N4 heterojunction (BBC) with an interlaced lattice was prepared, and the role of the interlaced lattice in charge transfer was revealed. Compared to pristine Bi2O2CO3, Bi2WO6, and C3N4, BBC exhibited an increased ciprofloxacin degradation rate constant (0.0573 min−1). A series of experiments were performed to reveal the role of the interlaced lattice interface in the enhanced photocatalytic performance. The results show that the driving force provided by the interlaced lattice interface changes the charge transfer mechanism from a dual Ⅱ-scheme to a dual S-scheme. 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subjects Bi2O2CO3
Bi2WO6
C3N4 quantum dots
Dual S-scheme heterojunction
Interlaced lattice interactions
title Internal electric fields drive dual S-scheme heterojunctions: Insights into the role of the triple interlaced lattice
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