Research Article
Investigation of Fe-Doped Graphitic Carbon Nitride-Silver Tungstate as a Ternary Visible Light Active Photocatalyst
Table 3
Comparison of the degradation performance of metal/nonmetal doped g-C3N4-based ternary photocatalysts.
| | Sr. no. | Photocatalysts | Fabrication methods | Target pollutants | Light source | Degradation time (min) | Photocatalytic activity (%) | References |
| | 1. | P-g–C3N4–ag2WO4 | Thermal polymerization method | Indomethacin | Visible light | 60 | 91 | [11] | | 2. | Ag-g-C3n4/FeWO4 | Hydrothermal | Rhodamine B | Visible light | 120 | 98 | [28] | | 3. | P–S-g-C3N4/Ag2CO3 | Ion-exchange deposition method | 2,4-Dinitrophenol | Visible light | 360 | 99 | [38] | | 4. | O-g-C3N4/ZnIn2S4 | Hydrothermal method | 2,4-Dinitrophenol | Visible light | 180 | 92 | [39] | | 5. | P–S-g-C3N4/Ag2VO3 | Ion-exchange deposition method | Phenol | Visible light | 360 | 99 | [40] | | 6. | Co/Fe-g-C3N4/MOFs | Hydrothermal method | Rhodamine B | UV/Vis | 30 | 99 | [12] | | 7. | Fe– C3N4/Ag2CO3 | Hydrothermal method | Rhodamine B | Visible light | 180 minutes | 97 | This work |
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