Enhanced photocatalytic activity of ZrO2-CdZrO3-S nanocomposites for degradation of Crystal Violet dye under sunlight

•Binary ZrO2-CdZrO3 and ternary ZrO2-CdZrO3-S nanocomposites synthesized by hydrothermal and hydrothermal/solid-state respectively.•The band-gap energy of ZrO2-CdZrO3 reduced from 4.19 eV to 2.00 eV due to the influence of sulfur in the crystal structure.•ZrO2-CdZrO3-S nanocomposites degraded azo dy...

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Published in:Journal of photochemistry and photobiology. A, Chemistry. Chemistry., 2022-04, Vol.426, p.113746, Article 113746
Main Authors: Tavakoli-Azar, Tayebeh, Mahjoub, Alireza, Seyed Sadjadi, Mirabdullah, Ghaznavi-Ghoushchi, M.B.
Format: Article
Language:English
Subjects:
Crystal Violet
Kinetics
Nanocomposites
Photocatalytic
Scavengers
Sunlight
ZrO2-CdZrO3-S
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Summary:•Binary ZrO2-CdZrO3 and ternary ZrO2-CdZrO3-S nanocomposites synthesized by hydrothermal and hydrothermal/solid-state respectively.•The band-gap energy of ZrO2-CdZrO3 reduced from 4.19 eV to 2.00 eV due to the influence of sulfur in the crystal structure.•ZrO2-CdZrO3-S nanocomposites degraded azo dye of Crystal Violet better than ZrO2-CdZrO3 under sunlight.•Active species of •OH and e- play a major role in the degradation of Crystal Violet by ZrO2-CdZrO3-S.•ZrO2-CdZrO3-S nanocomposites decomposed Crystal Violet 42x times faster than ZrO2-CdZrO3.•ZrO2-CdZrO3-S nanocomposites were stable after the fifth reuse. In this research binary and ternary nanocomposites of ZrO2-CdZrO3 and ZrO2-CdZrO3-Sxy with various sulfur contents (xy: 20%, 10%, and 5%) and synthesized through a two-stage hydrothermal method followed by solid-state approach. Since sulfur has structural and electronic properties similar to oxygen, it is a suitable replacement of oxygen in the structure. Moreover, due to the chemical interaction of sulfur on the surface of ZrO2-CdZrO3 with Zr and O atoms, it infers oxygen vacancies and lowers the band-gap energy. It also the increased specific surface area and creation of hierarchical pores led to have improved photocatalytic activities. The XRD analysis confirmed the formation of nanocomposites. FE-SEM, TEM, EDX and Map techniques were employed to identify the morphology and chemical composition of synthesized materials. FT-IR result exhibited the peak position and vibration modes related to metal oxides and metal sulfides in ZrO2-CdZrO3-Sxy nanocomposites. The specific surface area was determined by BET. The optical properties were investigated by DRS analysis and the band-gap energy (Ebg) was determined via Tauc plots. Based on the results, upon sulfur incorporation the edge absorption band of nanocomposites was shifted towards the visible area and Ebg showed a reduction from 4.99 eV for ZrO2-CdZrO3 to 2.00 eV for ZrO2-CdZrO3-S20. Photocatalytic performance and kinetics studies of the synthesized nanocomposites were evaluated in the degradation of Crystal Violet (CV) toxic dye under natural sunlight. The results revealed that the highest efficiency was observed for ZrO2-CdZrO3-S20 compared with ZrO2-CdZrO3 (95% vs. 19%) in the first 30 min of irradiation. Photodegradation rate of CV by ZrO2-CdZrO3-S20 nanocomposites followed the pseudo-second-order kinetic with R2 = 0.9119. The CV degradation rate by ZrO2-CdZrO3-S20 nanocomposites with a rate const
ISSN:1010-6030
1873-2666
DOI:10.1016/j.jphotochem.2021.113746