Enhancing Catalytic CO Oxidation over Co3O4 Nanowires by Substituting Co2+ with Cu2+

Zhou, Minjie; Cai, Lili; Bajdich, Michal; García‐Melchor, Max; Hong, Li; He, Jiajun; Wilcox, Jennifer; Wu, Weidong; Vojvodić, Aleksandra; Zheng, Xiaolin

doi:10.1021/acscatal.5b00488

Cited by 191 publications

(119 citation statements)

References 29 publications

(59 reference statements)

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“…[10,15,50,51] In contrast, some researchers revealed that the CO oxidation reactionm echanism can follow the LH mechanism, which includes the main four steps in CO oxidation:1 )COa dsorption on the cationic metal sites, 2) the formation of active oxygen that resultsf rom O 2 molecules adsorbed on oxygen vacancies, 3) the reaction of CO with active oxygen, and 4) CO 2 desorption from the catalyst surface. [10,15,50,51] In contrast, some researchers revealed that the CO oxidation reactionm echanism can follow the LH mechanism, which includes the main four steps in CO oxidation:1 )COa dsorption on the cationic metal sites, 2) the formation of active oxygen that resultsf rom O 2 molecules adsorbed on oxygen vacancies, 3) the reaction of CO with active oxygen, and 4) CO 2 desorption from the catalyst surface.…”

Section: Discussionmentioning

confidence: 99%

“…[10,15,50,51] In contrast, some researchers revealed that the CO oxidation reactionm echanism can follow the LH mechanism, which includes the main four steps in CO oxidation:1 )COa dsorption on the cationic metal sites, 2) the formation of active oxygen that resultsf rom O 2 molecules adsorbed on oxygen vacancies, 3) the reaction of CO with active oxygen, and 4) CO 2 desorption from the catalyst surface. According to previous studies, [9,10,15] the choice of as uitable doping cation can create structurald efects and residual stress as well as oxygen vacancies. These previous studies suggested that there are no clear reaction mechanisms on certain catalysts for CO oxidation and that tuningt he surface structurald efects (CO adsorption and the formation of active oxygen) of am aterial should be an efficient method to design new catalysts.…”

Section: Discussionmentioning

confidence: 99%

“…This strategy to prepare grafted ZIF-67@Co 3 O 4 and MOF-199@Co 3 O 4 precursor structures is based on as imple hydrothermals ynthesis methodt oo btain the Co 3 O 4 precursor and the subsequent in situ growth of ZIF-67 and MOF-199, respectively.T he morphologies of the Co 3 O 4 products can be tailoredb yc ontrolling the solvent polarity and concentration of precipitants. Zhou et al [15] revealed that Cu-substituted Co 3 O 4 -Cu x polycrystalline nanowires on 2in. These analysis resultsd emonstrate that irislike Co 3 O 4 exhibits ah igh catalytic activity for CO oxidation and contains an abundance of surface defect sites (Co 3+ + species) to result in an excellent low-temperature reducibility,o xygen vacancies and unsaturated chemicalb onds on the surface.…”

Section: Introductionmentioning

confidence: 99%

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Integrated Cobalt Oxide Based Nanoarray Catalysts with Hierarchical Architectures: In Situ Raman Spectroscopy Investigation on the Carbon Monoxide Reaction Mechanism

Zhang

et al. 2018

ChemCatChem

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Herein, a facile strategy for the in situ growth of a Co3O4‐based precursor with unique hierarchical architectures oriented diagonal or perpendicular to Ni surfaces is reported. This strategy to prepare grafted ZIF‐67@Co3O4 and MOF‐199@Co3O4 precursor structures is based on a simple hydrothermal synthesis method to obtain the Co3O4 precursor and the subsequent in situ growth of ZIF‐67 and MOF‐199, respectively. The morphologies of the Co3O4 products can be tailored by controlling the solvent polarity and concentration of precipitants. CO is chosen as a probe molecule to evaluate the catalytic performance of the as‐synthesized Co3O4‐based oxide catalysts, and the structure–activity relationships are confirmed by using TEM, H2 temperature‐programmed reduction, X‐ray photoelectron spectroscopy, Raman spectroscopy and in situ Raman spectroscopy, and extended X‐ray absorption fine structure analysis. These analysis results demonstrate that irislike Co3O4 exhibits a high catalytic activity for CO oxidation and contains an abundance of surface defect sites (Co3+ species) to result in an excellent low‐temperature reducibility, oxygen vacancies and unsaturated chemical bonds on the surface. Moreover, we used in situ Raman spectroscopy to record the structural transformation of Co3O4 directly during the reaction, which confirmed that CO oxidation on the surface of Co3O4 can proceed through the Langmuir–Hinshelwood mechanism (<200 °C) and the Mars–van Krevelen mechanism (>200 °C).

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Section: Discussionmentioning

confidence: 99%

“…[10,15,50,51] In contrast, some researchers revealed that the CO oxidation reactionm echanism can follow the LH mechanism, which includes the main four steps in CO oxidation:1 )COa dsorption on the cationic metal sites, 2) the formation of active oxygen that resultsf rom O 2 molecules adsorbed on oxygen vacancies, 3) the reaction of CO with active oxygen, and 4) CO 2 desorption from the catalyst surface. According to previous studies, [9,10,15] the choice of as uitable doping cation can create structurald efects and residual stress as well as oxygen vacancies. These previous studies suggested that there are no clear reaction mechanisms on certain catalysts for CO oxidation and that tuningt he surface structurald efects (CO adsorption and the formation of active oxygen) of am aterial should be an efficient method to design new catalysts.…”

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Integrated Cobalt Oxide Based Nanoarray Catalysts with Hierarchical Architectures: In Situ Raman Spectroscopy Investigation on the Carbon Monoxide Reaction Mechanism

Zhang

et al. 2018

ChemCatChem

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show abstract

“…In the S2p spectrum, the peak for sulfate ion of SO4 2-was confirmed at 169.7 eV. Compared to the peak positions between the Co/Al2O3 and Co/SO4 2-/Al2O3 catalysts before the de hydrogenation, the peak of cobalt species was slightly 20) . This phenomenon might derive from the interaction between sulfated ion (SO4 2-) and cobalt element to form CoSO4-like species.…”

Section: Catalyst Surfacementioning

confidence: 90%

Active Species of Sulfated Metal Oxide Catalyst for Propane Dehydrogenation

Watanabe

Hirata

Fukuhara

2017

J. Jpn. Petrol. Inst.

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This study focuses on clarifying the active species over a sulfated transition metal oxide (Cr, Mn, Fe, Co, Ni, Cu) catalyst for propane dehydrogenation. The unsulfated catalyst showed a high conversion for the dehydrogenation of propane, with significantly low selectivity to the desired product of propylene. On the other hand, the sulfated catalyst displayed a high selectivity to propylene, though the conversion was slightly decreased. The sulfation treatment was especially effective for the Co and Fe catalysts. The sulfate species (SO4 2-) were reduced to the active species of the sulfide ion (S 2-) in the reaction atmosphere, which increased a selectivity to propylene.

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“…[1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19] Up to now, many highly efficient catalysts for CO oxidation, mainly including supported noble metals (such as Au and Pt) 8,9,11,12,[19][20][21][22][23][24][25] and metal-oxides (such as Co 3 O 4 and MnO 2 ) have been successfully developed. 7,[13][14][15][16][17][18][26][27][28][29][30][31][32][33] For example, TiO 2 -supported Au catalyst is very active for CO oxidation at the temperature of −70 C. 19-21 SiO 2 -supported Pt-Fe catalysts give almost 100% CO conversion and 100% CO selectivity at room temperature. 8 Metal oxides are less expensive compared with supported noble metals, which enhances their potential for practical applications.…”

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confidence: 99%

Mesoporous Co‐Al oxide nanosheets as highly efficient catalysts for CO oxidation

Zhang

Wang

et al. 2020

AIChE Journal

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We report mesoporous Co‐Al oxide nanosheets (CoxAl‐Ns, where x denotes the Co/Al ratio in the samples) prepared by calcination of CoAl‐hydrotalcite and subsequent alkaline treatment. X‐ray diffraction, scanning electron microscopy, transmission electron microscopy, and X‐ray photoelectron spectroscopy measurements show that the prepared Co‐Al oxide nanosheets (CoxAl‐Ns) are very thin (10–15 nm) and exhibit high mesoporosity (3–5 nm). Catalytic CO oxidation tests reveal that the CoxAl‐Ns exhibit excellent catalytic performances at relatively low temperatures: for example, the Co2.5Al‐Ns catalyst could achieve 99% CO conversion at −98°C. Kinetic studies and experimental investigations indicate that the high activity of the Co2.5Al‐Ns sample is strongly related to the abundance of active sites associated with the large Brunauer–Emmett–Teller surface area. The Co2.5Al‐Ns catalyst also achieves full conversion of CO in tests performed with a gas mixture simulating automobile exhaust gas at 200°C. After loading the Co2.5Al‐Ns on a porous ceramic substrate, the obtained Co2.5Al‐Ns/PC shows high activity and stability in CO oxidation process. These features are potentially important for future industrial applications of these catalysts.

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Enhancing Catalytic CO Oxidation over Co₃O₄ Nanowires by Substituting Co²⁺ with Cu²⁺

Cited by 191 publications

References 29 publications

Integrated Cobalt Oxide Based Nanoarray Catalysts with Hierarchical Architectures: In Situ Raman Spectroscopy Investigation on the Carbon Monoxide Reaction Mechanism

Integrated Cobalt Oxide Based Nanoarray Catalysts with Hierarchical Architectures: In Situ Raman Spectroscopy Investigation on the Carbon Monoxide Reaction Mechanism

Active Species of Sulfated Metal Oxide Catalyst for Propane Dehydrogenation

Mesoporous Co‐Al oxide nanosheets as highly efficient catalysts for CO oxidation

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