Microstructure Evolution of a Co/MnO Catalyst for Fischer‐Tropsch Synthesis Revealed by <i>In Situ</i> XAFS Studies

Sun, Fanfei; Sun, Xueping; Jin, Yixing; Yang, Ruoou; Zhang, Hao; Liu, Yang; Song, Fei; Li, Xiaopeng; Wu, Dongshuang; Zhao, Tong; Jiang, Zheng

doi:10.1002/cctc.201900162

Cited by 6 publications

(3 citation statements)

References 38 publications

(21 reference statements)

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“…There is a major peak located at 1.45 Å, which corresponds to the Co−O coordination shell. 55 The major peak at 2.1 Å corresponding to the metallic shell of Co−Co indicates the presence of metallic Co, which is consistent with the results of XANES. Among them, CoMn− NC has the highest Co−Co peak, which indicates that it contains the greatest number of Co in nanoparticles.…”

Section: Resultssupporting

confidence: 87%

“…More detailed local structural information about Co atoms was obtained from the k 2 -weighted χ( k )-function EXAFS spectra, as shown in Figure (b). There is a major peak located at 1.45 Å, which corresponds to the Co–O coordination shell . The major peak at 2.1 Å corresponding to the metallic shell of Co–Co indicates the presence of metallic Co, which is consistent with the results of XANES.…”

Section: Resultssupporting

confidence: 87%

See 1 more Smart Citation

Efficient Decomposition of Ozone at Room Temperature by Cobalt-Organic ZIF-67 Nanostructure and Its Derivatives

Shen,

Wang,

et al. 2023

ACS Appl. Nano Mater.

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Catalytic decomposition of indoor ozone under high humidity conditions is a challenging and significant task. Co 2+ −centered ZIF-67 was used as the precursor material in this study, and the effect of metal−organic frameworks carbonization and secondary doping of transition metals on the activity was systematically investigated. Accordingly, the CoMn−NC catalyst exhibited a superhigh ozone conversion of 98.9% within 10 h at a concentration of 40 ppm of O 3 , relative humidity of 50%, and weight hourly space velocity of 360,000 mL/(g•h). The Co 0 cores in the nanoparticles and Co−N 2 centers generated during the carbonation process synergistically decompose ozone. The synergistic effect of Mn and Co can readily transfer electrons through the redox cycle, under the high surface oxygen conditions. The unique structure, a greater number of defect centers, and stronger peroxide desorption capability enable the catalyst to effectively avoid nanoparticle agglomeration and maintain relatively high activity over a long period of time.

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Section: Resultssupporting

confidence: 87%

Section: Resultssupporting

confidence: 87%

Efficient Decomposition of Ozone at Room Temperature by Cobalt-Organic ZIF-67 Nanostructure and Its Derivatives

Shen,

Wang,

et al. 2023

ACS Appl. Nano Mater.

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“…identified species, including CoO, Co2C, and cobalt-supported compounds [32]. Thus, dynamic structure characterization of Co nanoparticles under working conditions, such as sintering, dispersion, and oxidation (caused by water), has attracted interest even though this involves great challenges under harsh conditions [33,34].…”

Section: Fischer-tropsch (Ft) Synthesismentioning

confidence: 99%

Full life cycle characterization strategies for spatiotemporal evolution of heterogeneous catalysts

Zheng

Xie

2021

Chinese Journal of Catalysis

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Elucidating the Role of Bifunctional Cobalt‐Manganese Catalyst Interactions for Higher Alcohol Synthesis

Paterson¹,

Partington²,

Peacock³

et al. 2020

Eur J Inorg Chem

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Catalyst promoters are often used to tune or improve performance with little understanding as to how they work. Here we present a fundamental evaluation of cobalt‐manganese interactions in Fischer‐Tropsch (FT) catalysis and evaluate a new bifunctional catalyst for CO dissociation and CO insertion mechanisms. FT has gained considerable attention recently due to the potential to convert bio or municipal waste feeds into commercial fuels and chemicals. Products are commonly highly linear paraffins, but here we show how the role of manganese can tune selectivity for linear olefins and alcohols in a copper, iron and alkali metal free cobalt bifunctional catalyst. These products also have significant commercial value for lubricants, plasticizers, detergents and base chemicals. Advanced catalyst characterization is shown with in situ techniques (XRD, EXAFS, PDF & TEM), while the FT products are fully analysed by NMR, GC and GCxGC. The role of manganese during catalyst synthesis is reviewed while fundamental understanding of the formation of a mixed metal oxide spinel is presented. The Co–Mn interactions change during catalyst reduction, with EXAFS showing cobalt metal and MnO as the main species present.

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Microstructure Evolution of a Co/MnO Catalyst for Fischer‐Tropsch Synthesis Revealed by In Situ XAFS Studies

Cited by 6 publications

References 38 publications

Efficient Decomposition of Ozone at Room Temperature by Cobalt-Organic ZIF-67 Nanostructure and Its Derivatives

Efficient Decomposition of Ozone at Room Temperature by Cobalt-Organic ZIF-67 Nanostructure and Its Derivatives

Full life cycle characterization strategies for spatiotemporal evolution of heterogeneous catalysts

Elucidating the Role of Bifunctional Cobalt‐Manganese Catalyst Interactions for Higher Alcohol Synthesis

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