Selectivity descriptors for the direct hydrogenation of CO2 to hydrocarbons during zeolite-mediated bifunctional catalysis

Ramírez, Adrián; Gong, Xuan; Çağlayan, Mustafa; Nastase, Stefan A. F.; Abou‐Hamad, Edy; Gevers, Lieven; Cavallo, Luigi; Chowdhury, Abhishek Dutta; Gascón, Jorge

doi:10.1038/s41467-021-26090-5

Cited by 54 publications

(94 citation statements)

References 72 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For a more fundamental understanding, we refer to the book chapter by McKenzie and Rounder on this topic . Because of its ability to explore the mobility aspect of the reaction intermediate, the TF-μSR technique could be combined complementarily with the mobility-dependent solid-state NMR techniques to explore the host–guest chemistry in zeolite catalysis. , …”

Section: Radical Chemistry In Zeolite Catalysismentioning

confidence: 99%

“…If it is a descriptor, then can it control the product selectivity? The research groups, including us, Bao, Hemberger, Plessow/Studt, and Liu/Zheng strongly favor ketenes as a reaction intermediate. ,,,,− However, a few other studies proposed it to be unstable and highly reactive, and ketenes could accelerate the formation of coke species, which could lead to catalyst deactivation and, hence, the formation of ketenes is detrimental in zeolite catalysis. However, we can counterargue that this logic applies to all intermediates in zeolite catalysis and not necessarily to ketene.…”

Section: Ketene Chemistry In Zeolite Catalysismentioning

confidence: 99%

“…Although ketenes have not been detected directly, Ramirez et al also recently hypothesized that they play a crucial role during the hydrogenation of CO 2 over Fe 2 O 3 @KO 2 /zeolite catalysts (Figure ). To explain the zeolite-dependent selectivity preference during the reaction, they performed solid-state NMR spectroscopic investigation after the hydrogenation of 13 CO 2 . The postreacted zeolites demonstrated several carbonylated species in the 13 C– 13 C correlations spectra (Figure a), where the carbons were polarized through direct excitation, and 13 C– 13 C mixing was achieved through proton-driven spin-diffusion (PDSD): zeolite surface-acetate species (Θ, 176.6 ppm/19.2 ppm ( 13 C) on FER and 180.2/18.8 ppm in ZSM-22), acetone (Ω, 211.9 ppm/29.8 ppm), and diacetyl (∂, 197.5/23.05 ppm in ZSM-5, and ∂, 198.9/24.12 ppm in ZSM-22) .…”

Section: Ketene Chemistry In Zeolite Catalysismentioning

confidence: 99%

“… To explain the zeolite-dependent selectivity preference during the reaction, they performed solid-state NMR spectroscopic investigation after the hydrogenation of 13 CO 2 . The postreacted zeolites demonstrated several carbonylated species in the 13 C– 13 C correlations spectra (Figure a), where the carbons were polarized through direct excitation, and 13 C– 13 C mixing was achieved through proton-driven spin-diffusion (PDSD): zeolite surface-acetate species (Θ, 176.6 ppm/19.2 ppm ( 13 C) on FER and 180.2/18.8 ppm in ZSM-22), acetone (Ω, 211.9 ppm/29.8 ppm), and diacetyl (∂, 197.5/23.05 ppm in ZSM-5, and ∂, 198.9/24.12 ppm in ZSM-22) . Specifically, the simultaneous existence of acetone, acetate, and diacetyl groups strongly suggests the involvement of ketene (CH 2 CO) as an active reaction intermediate.…”

Section: Ketene Chemistry In Zeolite Catalysismentioning

confidence: 99%

“…Evidence of ketene’s indirect involvement as a reaction intermediate during hydrogenation of CO 2 over Fe 2 O 3 @KO 2 /zeolite bifunctional catalysts. (a) 13 C– 13 C correlations in the carbonyl regions on postreacted zeolites MOR (pink), FER (blue), ZSM-5 (yellow), and ZSM-22 (green), highlighting the presence of ester and ketones (*: spinning sidebands on ZSM-5) . (b) The proposed interconversion between ketene and other carbonylated intermediates (surface acetate, acetone, diacetyl) on zeolite .…”

Section: Ketene Chemistry In Zeolite Catalysismentioning

confidence: 99%

See 4 more Smart Citations

First-Generation Organic Reaction Intermediates in Zeolite Chemistry and Catalysis

Gong

Çağlayan

et al. 2022

Chem. Rev.

Self Cite

View full text Add to dashboard Cite

Zeolite chemistry and catalysis are expected to play a decisive role in the next decade(s) to build a more decentralized renewable feedstock-dependent sustainable society owing to the increased scrutiny over carbon emissions. Therefore, the lack of fundamental and mechanistic understanding of these processes is a critical “technical bottleneck” that must be eliminated to maximize economic value and minimize waste. We have identified, considering this objective, that the chemistry related to the first-generation reaction intermediates (i.e., carbocations, radicals, carbenes, ketenes, and carbanions) in zeolite chemistry and catalysis is highly underdeveloped or undervalued compared to other catalysis streams (e.g., homogeneous catalysis). This limitation can often be attributed to the technological restrictions to detect such “short-lived and highly reactive” intermediates at the interface (gas–solid/solid–liquid); however, the recent rise of sophisticated spectroscopic/analytical techniques (including under in situ/operando conditions) and modern data analysis methods collectively compete to unravel the impact of these organic intermediates. This comprehensive review summarizes the state-of-the-art first-generation organic reaction intermediates in zeolite chemistry and catalysis and evaluates their existing challenges and future prospects, to contribute significantly to the “circular carbon economy” initiatives.

show abstract

Section: Radical Chemistry In Zeolite Catalysismentioning

confidence: 99%

Section: Ketene Chemistry In Zeolite Catalysismentioning

confidence: 99%

Section: Ketene Chemistry In Zeolite Catalysismentioning

confidence: 99%

Section: Ketene Chemistry In Zeolite Catalysismentioning

confidence: 99%

Section: Ketene Chemistry In Zeolite Catalysismentioning

confidence: 99%

See 3 more Smart Citations

First-Generation Organic Reaction Intermediates in Zeolite Chemistry and Catalysis

Gong

Çağlayan

et al. 2022

Chem. Rev.

Self Cite

View full text Add to dashboard Cite

show abstract

Mapping the Methanol‐to‐Gasoline Process Over Zeolite Beta

Abou-Hamad

Gong

et al. 2023

Angewandte Chemie

Self Cite

View full text Add to dashboard Cite

Decarbonizing the transportation sector is among the biggest challenges in the fight against climate change. CO2‐neutral fuels, such as those obtained from renewable methanol, have the potential to account for a large share of the solution, since these could be directly compatible with existing power trains. Although discovered in 1977, the zeolite‐catalyzed methanol‐to‐gasoline (MTG) process has hardly reached industrial maturity, among other reasons, because maximizing the production of gasoline range hydrocarbons from methanol has proved complicated. In this work, we apply multimodal operando UV/Vis diffuse reflectance spectroscopy coupled with an online mass spectrometer and “mobility‐dependent” solid‐state NMR spectroscopy to better understand the reaction mechanism over zeolites H‐Beta and Zn‐Beta. Significantly, the influential co‐catalytic role of oxymethylene species is linked to gasoline formation, which impacts the MTG process more than carbonylated species.

show abstract

Tracking the Impact of Koch‐Carbonylated Organics During the Zeolite ZSM‐5 Catalyzed Methanol‐to‐Hydrocarbons Process

Zhou,

Gong,

Abou‐Hamad

et al. 2024

Angewandte Chemie

Self Cite

View full text Add to dashboard Cite

A methanol‐based economy offers an efficient solution to current energy transition challenges, where the zeolite‐catalyzed methanol‐to‐hydrocarbons (MTH) process would be a key enabler in yielding synthetic fuels/chemicals from renewable sources. Despite its original discovery over half a century ago over the zeolite ZSM‐5, the practical application of this process in a CO2‐neutral scenario has faced several obstacles. One prominent challenge has been the intricate mechanistic complexities inherent in the MTH process over the zeolite ZSM‐5, impeding its widespread adoption. This work takes a significant step forward by providing critical insights that bridge the gap in our understanding of the MTH process. It accomplishes this by connecting the (Koch‐carbonylation‐led) direct and dual cycle mechanisms, which operate during the early and steady‐state phases of MTH catalysis, respectively. To unravel these mechanistic intricacies, we have performed catalytic and operando (i.e., UV‐Vis coupled with an online mass spectrometer) and solid‐state NMR spectroscopic‐based investigations on the MTH process, involving co‐feeding methanol and acetone (cf. a key Koch‐carbonylated species), including selective isotope‐labeling studies. Our iterative research approach revealed that (Koch‐)carbonyl group selectively promotes the side‐chain mechanism within the arene cycle of the dual cycle mechanism, impacting the preferential formation of BTX fraction (i.e., benzene‐toluene‐xylene) primarily.

show abstract

Selectivity descriptors for the direct hydrogenation of CO2 to hydrocarbons during zeolite-mediated bifunctional catalysis

Cited by 54 publications

References 72 publications

First-Generation Organic Reaction Intermediates in Zeolite Chemistry and Catalysis

First-Generation Organic Reaction Intermediates in Zeolite Chemistry and Catalysis

Mapping the Methanol‐to‐Gasoline Process Over Zeolite Beta

Tracking the Impact of Koch‐Carbonylated Organics During the Zeolite ZSM‐5 Catalyzed Methanol‐to‐Hydrocarbons Process

Contact Info

Product

Resources

About