Abstract
Metal-organic frameworks (MOFs) have attracted significant research interest as promising innovative platforms for designing heterojunction photocatalysts. Herein, we report the rational design and preparation of an AgI@Sn-BDC-NH(2) heterojunction composite via a simple and facile in-situ route to degrade organic dyes (RhB). The AgI@Sn-BDC-NH(2) structural, surface, and optical characteristics were thoroughly examined by means of XRD, FTIR, SEM, EDS, UV-Vis DRS, VB-XPS, N(2) physisorption, TG, XPS, PL, transient photocurrent, and EIS techniques. The experimental results confirmed that AgI particles were dispersed on the surface of flower-like Sn-BDC-NH(2), and the introduction of AgI significantly boosts the photocatalytic performance of the nanocomposites. Under the operating parameters (catalyst dosage of 0.5 g/L, RhB concentration of 30 mg/L, volume of 40 mL, and illumination time of 60 min), the 30-AgI@Sn-BDC-NH(2) with the AgI loading of 30% exhibited the highest degradation efficiency in RhB, reaching 94.7%, with a photocatalytic rate constant of 0.039 min(- 1), which was 3.22 times and 26.0 times that of pure AgI and Sn-BDC-NH(2), respectively. The enhanced activity can be originated from the formation of Z-scheme heterojunction between AgI and Sn-BDC-NH(2) with intimate interfacial contact and the synergistic effects among the components, thereby providing a mesoporous structure and larger relative surface area (27.9 m(2)/g), improving utilization of visible light, more charge transfer channels, and lower electron-hole pair recombination rates. More crucially, it retained 78.1% degradation efficiency after five cycles, confirming excellent stability. Furthermore, trapping analyses suggest that e(-), •O(2)(-), and h(+) radicals dominate the degradation reaction pathway, and then a possible mechanism of 30-AgI@Sn-BDC-NH(2) Z-scheme heterojunction was proposed. Overall, this research work highlights the potential of using Sn-MOF-based heterojunction composites as practical photocatalysts for sustainable dye-contaminated wastewater treatment.