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Abstract
Although both MoS2 and nanoscale zero valent iron have presented bright prospects for environmental remediation. The constrained conductivity of MoS2 and the passivation and aggregation of Fe0 still retained challenges. Given this, innovative strategies of activating the passivation layers of Fe0 into semiconductors by photocatalysis and constructing S-scheme nanoflower heterojunctions with MoS2 (Fe0@MoS2) were fabricated. The results revealed that Fe0@MoS2 exhibited enhanced efficiency toward visible-light degradation of tetracycline, which was 3.20 and 1.27 times as high as that of bare MoS2 and Fe0, respectively. The boosted activity was attributed to the cooperation of MoS2 and Fe0. The synergistic effects stemmed from the following mechanisms: (1) the fluffy nanoflower-like structure and widened interlayer spacing of MoS2 facilitated the dispersion of Fe0, guaranteeing its enhanced adsorption and reduction capacity; (2) the conductivity of MoS2 was remarkably improved due to the doping of the passivation layers of Fe0, and the layers were activated as semiconductors by visible-light, causing the establishment of S-scheme heterojunctions between them and MoS2. Moreover, the kinetics, stability, recyclability, and optical characteristics of Fe0@MoS2 were confirmed comprehensively. The potential routes for TC elimination deriving from the action of •O2− and h+ were proposed. These findings provided novel strategies for construction of Fe0-based S-scheme heterojunction with advanced visible-light-induced degradation performance.
Original language | English |
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Article number | 135865 |
Number of pages | 12 |
Journal | Journal of Cleaner Production |
Volume | 388 |
Early online date | 4 Jan 2023 |
DOIs | |
Publication status | Published - 15 Feb 2023 |
Bibliographical note
Funding Information:This work was supported by the National Natural Science Foundation of China (NSFC, Grant No. 51968031 ), State Scholarship Fund of China Scholarship Council (CSC) via which Xiangyu Wang was a visiting Professor at the University of Birmingham, the Engineering and Physical Sciences Research Council Impact Acceleration Accounts Developing Leaders (Grant No. 1001634 ), and EU H2020 projects NanoSolveIT (Grant Agreement 814572 ), RiskGone (Grant Agreement 814425 ), NanoCommons (Grant Agreement 731032 ) and CompSafeNano (Grant Agreement 101008099 ).
Publisher Copyright:
© 2023
Keywords
- MoS nanoflower
- Nanoscale zero valent iron
- S-scheme heterojunction
- Synergistic effect
- Tetracycline photodegradation
ASJC Scopus subject areas
- Renewable Energy, Sustainability and the Environment
- Building and Construction
- Environmental Science(all)
- Strategy and Management
- Industrial and Manufacturing Engineering
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CompSafeNano: NanoInformatics Approaches for Safe-by-Design NanoMaterials
1/09/21 → 31/08/25
Project: EU
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H2020_RIA_NANOCOMMONS_CO-ORDINATOR
Valsami-Jones, E., Lynch, I. & Gkoutos, G.
1/01/18 → 30/06/22
Project: EU