Effect of Calcination Temperature on Catalytic Performance of CeCu Oxide in Removal of Quinoline by Wet Hydrogen Peroxide Oxidation from Water

Jiao, Zhaojie; Zhou, Guilin; Zhang, Haidong; Shen, Yu; Zhang, Xianming; Li, Juexuan; Gao, Xu

doi:10.21577/0103-5053.20180100

Cited by 5 publications

(7 citation statements)

References 23 publications

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“…The crystalline phase structure, pore structure, and surface morphology of the catalyst did not change significantly before and after the reaction. On the one hand, it may have been due to the fact that Cu 2+ dissolved into the CeO 2 lattice to form CeCu oxide solid solution, which resulted in strong interaction between CuO and CeO 2 and enhanced the stability of the catalyst; on the other hand, it may be due to the addition of rare earth element Ce, which can disperse and stabilize the active components of the catalyst and improve its acidity resistance and prevent volume shrinkage, thereby improving the structural stability of the catalyst to a certain extent [30].…”

Section: Resultsmentioning

confidence: 99%

“…The peaks ranging from 529.8–531 eV belonged to the absorption oxygen O 2 2− or O − species on the catalyst surface. The peak at 531.6 eV was from the hydroxyl oxygen OH − [30] of absorbed water on catalyst surface. From the comparison of O1s XPS spectra before and after the reaction, the O1s XPS peak of CC450 catalyst shifted slightly to the right after five reuses, indicating that lattice oxygen content was gradually dominant and stable crystal phase CuO might gradually form on the catalyst surface, with some loose amorphous species lost along with the reaction.…”

Section: Resultsmentioning

confidence: 99%

“…According to the degradation pathway, CeCu oxide catalysts in heterogeneous CWPO reaction system may have mainly produced strong oxidative ·OH radicals by catalyzing H 2 O 2 to achieve oxidative degradation of organic compounds. It was found that the prepared CeCu oxide catalyst formed a CeCu oxide solid solution at high temperature, and some Cu + and Cu 2+ replaced Ce 4+ in the CeO 2 lattice, which destroyed the coordination balance of CeO 2 lattice and formed a pair of Cu 2+ and Ce 3+ /Ce 4+ ions between CuO and CeO 2 [30], resulting in oxygen vacancy. Oxygen vacancy may be beneficial to the adsorption and activation of H 2 O 2 [25].…”

Section: Resultsmentioning

confidence: 99%

“…Materials containing Cu 2+ /Cu + , such as iron and other metals, could produce hydroxyl radical in catalyzing hydrogen peroxide, and also have a higher ability to degrade BPA [25]. However, the Cu-based catalyst leads to the loss of active components in the CWPO process, and the preparation process of some catalysts is relatively complicated [24,26,30]. Therefore, this paper intends to prepare a catalyst with simple structure and strong stability, which could also show high catalytic activity and adapt to wide pH ranges.…”

Section: Introductionmentioning

confidence: 99%

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Degradation of Bisphenol A by CeCu Oxide Catalyst in Catalytic Wet Peroxide Oxidation: Efficiency, Stability, and Mechanism

Jiao

Chen

Zhou

et al. 2019

IJERPH

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The CeCu oxide catalyst CC450 was prepared by citric acid complex method and the catalytic wet peroxide oxidation (CWPO) reaction system was established with bisphenol A (BPA) as the target pollutant. By means of characterization, this research investigated the phase structure, surface morphology, reducibility, surface element composition, and valence of the catalyst before and after reuse. The effects of catalyst dosage and pH on the removal efficiency of BPA were also investigated. Five reuse experiments were carried out to investigate the reusability of the catalyst. In addition, this research delved into the changes of pH value, hydroxyl radical concentration, and ultraviolet-visible spectra of BPA in CWPO reaction system. The possible intermediate products were analyzed by gas chromatography-mass spectrometry (GC-MS). The catalytic mechanism and degradation pathway were also discussed. The results showed that after reaction of 65 min, the removal of BPA and total organic carbon (TOC) could reach 87.6% and 77.9%, respectively. The catalyst showed strong pH adaptability and had high removal efficiency of BPA in the range of pH 1.6–7.9. After five reuses, the removal of BPA remained above 86.7%, with the structure of the catalyst remaining stable to a large extent. With the reaction proceeding, the pH value of the reaction solution increased, the concentration of OH radicals decreased, and the ultraviolet-visible spectrum of BPA shifted to the short wavelength direction, that is, the blue shift direction. The catalysts degraded BPA rapidly in CWPO reaction system and the C–C bond or O–H bond in BPA could be destroyed in a very short time. Also, there may have been two main degradation paths of phenol and ketone.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Degradation of Bisphenol A by CeCu Oxide Catalyst in Catalytic Wet Peroxide Oxidation: Efficiency, Stability, and Mechanism

Jiao

Chen

Zhou

et al. 2019

IJERPH

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“…In particulates, beyond relevant sintering, temperature initiates the grain growth and agglomerate formation and aggregation was increased leading to the densification. At the time of calcination, oxidation and reduction takes place, which encourages the removal of water and gas phases together with impurities (Jiao et al, 2018; Rhamdhani, Jak, Hayes, & Nicke, 2008). By varying the sintering temperature, amorphous bioactive glasses turn to semicrystalline nature with the grain growth owing to Ostwald ripening (Carter & Norton, 2007).…”

Section: Introductionmentioning

confidence: 99%

Thermal treatment stimulus on erythrocyte compatibility and hemostatic behavior of one‐dimensional bioactive nanostructures

Chitra

Bargavi

et al. 2020

J Biomedical Materials Res

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This study identifies the role and significance of heat treatment parameters on blood compatibility and hemostatic performances. Bioactive nanomaterials step annealed at 550 and 600°C enhances the biocompatibility due to the liberation of nitrate content. This also develops the anisotropic structures such as needle‐like and rod‐like appearances that positively improve the erythrocyte compatibility. Different stable crystalline phases such as NaCaPO4, Na2Ca2Si3O9, and Na1.8Ca1.1Si6O14 were observed for all the bioactive materials, whereas in the case of 800°C, phase transition of Na3CaPSiO7 was perceived along with P2O5. Alternatively, morphology varied from cubical (600°C) to rod‐like (step annealing) and further turned toward flake‐like (800°C) structures. Step‐annealing process decomposed the nitrate groups as well as maintained the glass network without altering the crystalline phases. As a result, bioactive nanomaterials subjected to step annealing at 550°C along with 600°C exhibited superior compatibility with erythrocytes. Bioglass heat treated at 800°C revealed incredible blood clotting efficacy, in which Ca2+ ions initiated the thrombotic effect, blood components were concentrated due to the effect of calcium, and enhances the hemostatic performance. Bioactive glass annealed below 800°C facilitates the biocompatibility, subsequently encourage bone ingrowths at in vivo. Bioglass‐800°C inspired the fibrin formation and induced clot as a hemostat to control hemorrhage.

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CuO-doped Ce for catalytic wet peroxide oxidation degradation of quinoline wastewater under wide pH conditions

Jiao

Zhang

Gong

et al. 2022

Journal of Industrial and Engineering Chemistry

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Effect of Calcination Temperature on Catalytic Performance of CeCu Oxide in Removal of Quinoline by Wet Hydrogen Peroxide Oxidation from Water

Cited by 5 publications

References 23 publications

Degradation of Bisphenol A by CeCu Oxide Catalyst in Catalytic Wet Peroxide Oxidation: Efficiency, Stability, and Mechanism

Degradation of Bisphenol A by CeCu Oxide Catalyst in Catalytic Wet Peroxide Oxidation: Efficiency, Stability, and Mechanism

Thermal treatment stimulus on erythrocyte compatibility and hemostatic behavior of one‐dimensional bioactive nanostructures

CuO-doped Ce for catalytic wet peroxide oxidation degradation of quinoline wastewater under wide pH conditions

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