doi: 10.1038/s42004-022-00707-2.
A BaTiO3/WS2 composite for piezo-photocatalytic persulfate activation and ofloxacin degradation
Affiliations
- PMID: 36697648
- PMCID: PMC9814951
- DOI: 10.1038/s42004-022-00707-2
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A BaTiO3/WS2 composite for piezo-photocatalytic persulfate activation and ofloxacin degradation
Commun Chem.
.
Abstract
Piezoelectric fields can decrease the recombination rate of photogenerated electrons and holes in semiconductors and therewith increase their photocatalytic activities. Here, a BaTiO3/WS2 composite is synthesized and characterized, which combines piezoelectric BaTiO3 nanofibers and WS2 nanosheets. The piezo-photocatalytic effect of the composite on the persulfate activation is studied by monitoring Ofloxacin (OFL) degradation efficiency. Under mechanical forces, LED lamp irradiation, and the addition of 10 mM persulfate, the OFL degradation efficiency reaches ~90% within 75 min, which is higher than efficiencies obtained for individual BaTiO3, WS2, or TiO3, widely used photocatalysts in the field of water treatment. The boosted degradation efficiency can be ascribed to the promotion of charge carrier separation, resulting from the synergetic effect of the heterostructure and the piezoelectric field induced by the vibration. Moreover, the prepared composite displays good stability over five successive cycles of the degradation process. GC-MS analysis is used to survey the degradation pathway of OFL during the degradation process. Our results offer insight into strategies for preparing highly effective piezo-photocatalysts in the field of water purification.
© 2022. The Author(s).
Conflict of interest statement
The authors declare no competing interests.
Figures
a The XRD and b FT-IR spectra of the pure BaTiO3, WS2, and BaTiO3/WS2. High-resolution XPS spectra of c Ba 3d, d Ti 2p, and e W 4 f of BaTiO3/WS2 composite.
a–c SEM, and d–f TEM images of WS2, BaTiO3, and the BaTiO3/WS2 composite, respectively. g HR-TEM image of the BaTiO3/WS2 composite and d-spacing calculated for h BaTiO3 and i WS2 using the selected areas on HR-TEM.
a The SEM image and b–g SEM elemental mapping of the BaTiO3/WS2 composite. h The EDX spectra correspond to the composite (inserted Table: quantitative results obtained for W, S, O, Ba, and Ti).
a Synergistic effect of the piezo-photocatalytic assisted activation of persulfate. b Comparison of the piezo-photocatalytic activity of the BaTiO3/WS2 composite with the pure TiO2, BaTiO3, and WS2 and. Experimental conditions: Catalyst concentration = 1.0 g L−1, [OFL] = 20 mg L−1, [PS] = 10 mM, pH = 6.5. The error bars were not shown, as they were smaller than the data points.
a Effect of catalyst concentration, c the effect of initiate pH, d various OFL concentrations, e bath ultrasonic power, and f persulfate concentration on the piezo-photocatalytic degradation of OFL. b pHpzc of BaTiO3/WS2 nanocomposite. Experimental conditions: Catalyst concentration = 1.0 g L−1, [OFL] = 20 mg L−1, [PS] = 10 mM, pH = 6.5. The error bars were not shown, as they were smaller than the data points.
a The piezo-photocatalytic degradation efficiency of OFL and b XRD patterns of the BaTiO3/WS2 composite before and after five successive cycles. Experimental conditions: Catalyst concentration = 1.0 g L−1, [OFL] = 20 mg L−1, [PS] = 10 mM, pH = 6.5.
a The effect of diverse scavengers on the piezo-photocatalytic degradation of OFL in the presence of PS, b Fluorescence spectra of the materials in the presence of AgNO3, c–h high-resolution XPS spectra of W, Ba, and Ti before and after contact of WS2 and BaTiO3, and i–k the proposed schematic mechanism for the charge-carrier transference of the BaTiO3/WS2 composite. Experimental condition: Catalyst concentration = 1.0 g L−1, [OFL] = 20 mg L−1, pH = 6.5, [Scavengers] = 5 mmol L−1. The error bars were not shown, as they were smaller than the data points.
Proposed reaction pathways for OFL based on the determined by-products.
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