Chapter 5. Present and future prospects in heterogeneous catalysts for C1 chemistry

Lee, Eunmin; Cheng, Zhuo; Lo, Cynthia S.

doi:10.1039/9781782622697-00187

Cited by 5 publications

(2 citation statements)

References 113 publications

(140 reference statements)

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“…27 Methane reforming to syngas is strongly endothermic and requires temperatures above 600 °C. 28 The most widely used technologies include steam reforming (SRM), 29−31 dry reforming (DRM), 32,33 partial oxidation (POM), 34,35 and autothermal reforming (ARM). 36,37 The used catalysts, oxidants, H 2 /CO ratio, and energetics differ between these processes.…”

Section: Introductionmentioning

confidence: 99%

“…Currently utilized commercial routes for methane activation involve the methane conversion into syngas via a reforming reaction, and the subsequent conversion into fuels or chemicals . Methane reforming to syngas is strongly endothermic and requires temperatures above 600 °C . The most widely used technologies include steam reforming (SRM), − dry reforming (DRM), , partial oxidation (POM), , and autothermal reforming (ARM). , The used catalysts, oxidants, H 2 /CO ratio, and energetics differ between these processes .…”

Section: Introductionmentioning

confidence: 99%

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Significant Advances in C1 Catalysis: Highly Efficient Catalysts and Catalytic Reactions

et al. 2019

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C1 catalysis refers to the conversion of simple carbon-containing compounds, such as carbon monoxide, carbon dioxide, methane, and methanol into high-value-added chemicals, petrochemical intermediates, and clean fuels. Because of the rising oil price and the apprehension of fossil fuel depletion in the future, C1 catalysis has been attracting widespread academic and industrial interest and became one of the most attractive research fields in heterogeneous catalysis. Especially in recent years, benefiting from advanced technology development, precise and controllable material synthesis methods, and powerful computational simulation capabilities, C1 catalysis has achieved remarkable progress in many aspects, including insights into the reaction mechanism, identification of active-site structures, highly efficient catalysts and reaction process, and the reactor designs. This Review highlights the latest developments (from 2012 to 2018) in highly efficient catalyst systems and reaction processes in this field. The content covers the catalytic utilization of the four molecules including carbon monoxide, carbon dioxide, methane, and methanol. The catalytic performances of these highly efficient systems, including activity, selectivity, and stability, are introduced in detail and compared to previously reported catalysts. Furthermore, the established relationships between reactivity and active-site structure are clarified. Finally, current challenges and perspectives for future research are discussed.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Significant Advances in C1 Catalysis: Highly Efficient Catalysts and Catalytic Reactions

et al. 2019

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Hydrogen/Deuterium‐Exchange Reactions of Methane with Aromatics and Cyclohexane Catalyzed by a Nanoscopic Aluminum Chlorofluoride

2017

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H/D-exchange reactions between methane and deuterated solvents such as [D 6 ]benzene and [D 12 ]cyclohexane were heterogeneouslyc atalyzed by nanoscopic aluminum chlorofluoride (ACF = AlCl x F 3Àx , x % 0.05-0.3) under very mild conditions. 13 CNMR spectroscopy experiments at labeled methane revealed the formationo fa ll isotopologues. AlCl 3 ,A lBr 3 ,H S-AlF 3 , g-Al 2 O 3 ,a nd g-Al 2 O 3 preheated at 700 8Cd id not show any H/D-exchange reactionofmethane or [D 6 ]benzene. Mechanistically,e lectrophilic activation of methane was suggesteda tt he ACF surface.

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Carbon Dioxide Adsorption on CeO₂(110): An XPS and NEXAFS Study

Yang

Bebensee

et al. 2017

ChemPhysChem

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The adsorption of CO on the surface of a CeO (110) bulk single crystal was studied by X-ray photoelectron spectroscopy (XPS) and near-edge X-ray absorption fine structure (NEXAFS) spectroscopy. The high-quality XPS and C K-edge NEXAFS data show that CO adsorbs as a carbonate species on both fully oxidized CeO (110) and partially reduced CeO (110). No evidence for the formation of a carboxylate (CO ) intermediate could be found. On the fully oxidized CeO (110) substrate, the carbonate decomposes upon heating to above 400 K, leading to the desorption of CO . The NEXAFS data reveal the presence of a minor amount of formate (or carboxylate) and bicarbonate species, which are related to reactions of CO with surface hydroxyl groups. In the case of reduced CeO (110), the carbonate species completely disappear upon heating to temperatures above 500 K. In contrast to conclusions presented in earlier works, the oxidation state of the surface is unchanged, that is, CO does not re-oxidize the reduced CeO (110) surface.

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Chapter 5. Present and future prospects in heterogeneous catalysts for C1 chemistry

Cited by 5 publications

References 113 publications

Significant Advances in C1 Catalysis: Highly Efficient Catalysts and Catalytic Reactions

Significant Advances in C1 Catalysis: Highly Efficient Catalysts and Catalytic Reactions

Hydrogen/Deuterium‐Exchange Reactions of Methane with Aromatics and Cyclohexane Catalyzed by a Nanoscopic Aluminum Chlorofluoride

Carbon Dioxide Adsorption on CeO₂(110): An XPS and NEXAFS Study

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Chapter 5. Present and future prospects in heterogeneous catalysts for C1 chemistry

Cited by 5 publications

References 113 publications

Significant Advances in C1 Catalysis: Highly Efficient Catalysts and Catalytic Reactions

Significant Advances in C1 Catalysis: Highly Efficient Catalysts and Catalytic Reactions

Hydrogen/Deuterium‐Exchange Reactions of Methane with Aromatics and Cyclohexane Catalyzed by a Nanoscopic Aluminum Chlorofluoride

Carbon Dioxide Adsorption on CeO2(110): An XPS and NEXAFS Study

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Carbon Dioxide Adsorption on CeO₂(110): An XPS and NEXAFS Study