Catalytic activities and properties of mesoporous sulfated Al2O3–ZrO2

Zhao, Jinxin; Yue, Yinghong; Hua, Weiming; Gao, Zi

doi:10.1007/s10562-007-9085-x

Cited by 15 publications

(4 citation statements)

References 41 publications

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“…The mean pore diameter of the T10Z-500 sample is effectively the lowest one, obtained by the BJH method from the corresponding adsorption and desorption data. The obtained specific surface areas are in agreement with those reported by other authors [49,50].…”

Section: Macro-mesoporositysupporting

confidence: 92%

Enhanced Photocatalytic Activity of Hierarchical Macro-Mesoporous Anatase byZrO2Incorporation

García-Benjume

Espitia-Cabrera

Contreras-Garcı́a

2012

International Journal of Photoenergy

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The effect of the addition of zirconia in the photocatalytic behaviour of titania is analysed. In order to increase the ways for reagent and product diffusion in the material, a sol-gel hydrothermal synthesis route using Tween-20 as a directing agent to obtain a hierarchical macro-mesoporous structure is proposed. Nanostructured macro-mesoporous TiO2/ZrO2photocatalyst with 0, 10, 20, 30, and 100% mol of ZrO2were obtained and calcined at different temperatures. The crystalline structure was analyzed by X-ray diffraction and TEM. The porosity was confirmed by SEM, TEM, and nitrogen adsorption-desorption isotherms. The worm-like mesoporous structure was confirmed by TEM. The specific surface areas obtained by Brunauer-Emmet-Teller method (BET) ranged from 125 to 180 m2/g. The Tween-20 total elimination from the structure by thermal treatment was confirmed by infrared spectroscopy and thermogravimetric analysis. Additionally, the photocatalytic effect of the zirconia addition was studied in the methylene blue (MB) degradation reaction, and the best photocatalytic activity was obtained in the sample with 10% mol of ZrO2, degrading up to 92% the MB.

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Section: Macro-mesoporositysupporting

confidence: 92%

Enhanced Photocatalytic Activity of Hierarchical Macro-Mesoporous Anatase byZrO2Incorporation

García-Benjume

Espitia-Cabrera

Contreras-Garcı́a

2012

International Journal of Photoenergy

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“…Upon comparing the TPD profiles of CeSn/Ti with those of K/CeSn/Ti, Pb/ CeSn/Ti, and K/Pb/CeSn/Ti catalysts, it could be found that K greatly decreased the amount of weak acid (below 200 °C) and Pb impaired the middle acid (200−400 °C) and strong acid (above 400 °C). 22,23 However, the reduction of acid sites in CeSn/Ti-SA catalysts varied from that in CeSn/Ti catalysts, the main loss in acidity of the poisoned catalysts (K/CeSn/Ti-SA, Pb/CeSn/Ti-SA, and K/Pb/CeSn/Ti-SA) was the superacid sites from SO 4 2− (above 600 °C), 24 other acid sites did not change much, indicating that K or/and Pb would preferentially impair the superacid sites instead of other acid sites. To further quantify the above conclusions, the amount of NH 3 desorption was calculated to illustrate the change in the acid amount of the catalyst before and after poisoning (Table S2), 25 the calculated results were in accord with the results observed in Figure 2A.…”

Section: Resultsmentioning

confidence: 99%

Self-Protected CeO₂–SnO₂@SO₄^2–/TiO₂ Catalysts with Extraordinary Resistance to Alkali and Heavy Metals for NO_x Reduction

Cai

Wang

et al. 2020

Environ. Sci. Technol.

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Reducing the poisoning effect of alkali and heavy metals over ammonia selective catalytic reduction (NH3-SCR) catalysts is still an intractable issue, as the presence of K and Pb in fly ash greatly hampers their catalytic activity by impairing the acidity and affecting the redox properties of the catalysts, leading to the reduction in the lifetime of SCR catalysts. To address this issue, we propose a novel self-protected antipoisoning mechanism by designing SO4 2–/TiO2 superacid supported CeO2–SnO2 catalysts. Owing to the synergistic effect between CeO2 and SnO2 and the strong acidity originating from the SO4 2–/TiO2 superacid, the catalysts show superior catalytic activity over a wide temperature range (240–510 °C). Moreover, when K or/and Pb are deposited on SO4 2–/TiO2 catalysts, the bond effect between SO4 2– and Ti–O would be broken so that the sulfate in the bulk of SO4 2–/TiO2 superacid support would be induced to migrate to the surface to bond with K and Pb, thus prohibiting poisons from attacking the Ce–Sn active sites, and significantly boosting the resistance. Hopefully, this novel self-protection mechanism derived from the migration of sulfate in the SO4 2–/TiO2 superacid to resist alkali and heavy metals provides a new avenue for designing novel catalysts with outstanding resistance to alkali and heavy metals.

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“…These acids which are usually associated with two catalytic sites are able to activate a wide range of substrates because of the presence of both Brønsted and Lewis acidic sites . In this regard, Jing and co‐workers had made an interesting observation that solid acid SO 4 2 − /TiO 2 prepared at various calcination temperatures exhibited Lewis and Brønsted acidities to different extents, as confirmed from their in situ FIIR‐pyridine absorption frequencies at 1450 cm −1 and 1540 cm −1 respectively. It appears that ionic mode of mechanism is greatly assisted by the presence of a water source which can readily convert Lewis acidic sites into active Brønsted acids to activate the aldimines through ion‐pair formation in a typical Mannich reaction, as depicted in Figure .…”

Section: Introductionmentioning

confidence: 98%

Utilization of Solid Acid SO₄²⁻/TiO₂ as Catalyst to the Three‐Component Mannich Reaction at Ambient Temperature

Yao

Zhang

Chen

et al. 2017

Journal of Heterocyclic Chem

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in Wiley Online Library (wileyonlinelibrary.com). The three-component Mannich reaction of among dimethyl malonate, aromatic primary amine, and aromatic aldehyde was made successfully in the presence of solid acidic catalyst SO 4 2À /TiO 2 , with excellent catalytic activity, as compared to SO 4 2À /γ-Al 2 O 3 and SO 4 2À /ZnO. To the best of our knowledge, SO 4 2À / TiO 2 prepared at varied calcination temperatures can perform different intensities of Lewis and Brønsted acidities. Because of this point, under the optimum conditions, the effect of SO 4 2À /TiO 2 (prepared at 200°C) was much more than that of SO 4 2À /TiO 2 (prepared at 300°C or 400°C) in the three-component Mannich reaction. In observing ionization activation mode of the three-component Mannich reaction, it disclosed that the plausible mechanism possibly undergoes formation of aldimines and transformation of aldimines into β-amino esters by applying solid acidic catalyst SO 4 2À /M x O y . Dimethyl-2-((4-methylbenzo[d]thiazol-2-ylamino)(2-fluorophenyl)methyl)malonate (8). As a colorless oil, yield: 25%;1 H-NMR (500 MHz, CDCl 3 , 25°C, TMS): δ (ppm) 7.46 (t, J = 7.4 Hz, 1H), 7.39 (d, J = 8.0 Hz, 1H), 7.23-7.31 (m, 1H), 7.05 (q, J = 7.4 Hz, 3H), 6.99 (t, J = 8.0 Hz, 1H), 2526

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Catalytic activities and properties of mesoporous sulfated Al2O3–ZrO2

Cited by 15 publications

References 41 publications

Enhanced Photocatalytic Activity of Hierarchical Macro-Mesoporous Anatase byZrO2Incorporation

Enhanced Photocatalytic Activity of Hierarchical Macro-Mesoporous Anatase byZrO2Incorporation

Self-Protected CeO₂–SnO₂@SO₄^2–/TiO₂ Catalysts with Extraordinary Resistance to Alkali and Heavy Metals for NO_x Reduction

Utilization of Solid Acid SO₄²⁻/TiO₂ as Catalyst to the Three‐Component Mannich Reaction at Ambient Temperature

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Catalytic activities and properties of mesoporous sulfated Al2O3–ZrO2

Cited by 15 publications

References 41 publications

Enhanced Photocatalytic Activity of Hierarchical Macro-Mesoporous Anatase byZrO2Incorporation

Enhanced Photocatalytic Activity of Hierarchical Macro-Mesoporous Anatase byZrO2Incorporation

Self-Protected CeO2–SnO2@SO42–/TiO2 Catalysts with Extraordinary Resistance to Alkali and Heavy Metals for NOx Reduction

Utilization of Solid Acid SO42−/TiO2 as Catalyst to the Three‐Component Mannich Reaction at Ambient Temperature

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Self-Protected CeO₂–SnO₂@SO₄^2–/TiO₂ Catalysts with Extraordinary Resistance to Alkali and Heavy Metals for NO_x Reduction

Utilization of Solid Acid SO₄²⁻/TiO₂ as Catalyst to the Three‐Component Mannich Reaction at Ambient Temperature