Coke Formation and Regeneration during Fe-ZSM-5-Catalyzed Methane Dehydro-Aromatization

Karpe, Sanjana; Veser, Götz

doi:10.3390/catal14050292

Catalysts

2024

DOI: 10.3390/catal14050292

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Coke Formation and Regeneration during Fe-ZSM-5-Catalyzed Methane Dehydro-Aromatization

Sanjana Karpe,

Götz Veser

Abstract: Coke formation poses a significant obstacle in the direct conversion of methane into valuable chemicals such as ethylene, benzene, and hydrogen via methane dehydro-aromatization (MDA). At the elevated temperatures necessary for this reaction, coke is the thermodynamically favored product, causing rapid catalyst deactivation and hence necessitating frequent catalyst regeneration. Successful industrial implementation of MDA requires the advancement of catalyst regeneration processes and a comprehensive understan… Show more

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2024

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Cited by 2 publications

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Reaction Fundamentals and Reactor Configuration for Methane Dehydroaromatization: Present State and Future Prospects

Vatankhah,

Shabanian,

Mokhtari

et al. 2024

Energy Fuels

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Natural gas, mainly composed of methane, has gained attention in conversion technologies due to its increased supply and low prices relative to crude oil. It is important in the current energy landscape, and its significance is expected to persist in the future, supporting the transition toward a more sustainable and low-carbon future. The conversion of natural gas into chemicals with added value offers a way to utilize this abundant resource, while promoting energy security and decreasing pollutant emissions. However, direct nonoxidative methane dehydroaromatization (MDA) is still in the initial research stage, and there are uncertainties about enhancement approaches to create a commercially feasible process. We, hence, conducted a thorough review of critical factors that influence the development of efficient MDA processes. These factors include thermodynamic constraints, catalyst design, reaction mechanism, and kinetic models, methane activation pathways, catalyst activity, and selectivity toward desired products. As the core of this review, we discussed various reactor configurations for the MDA process, including packed bed, fluidized bed, membrane-assisted, plasma, and microwave reactors. Detailed analyses were conducted to assess these reactors' strengths, weaknesses, opportunities, and threats. These analyses help select an effective reactor that not only overcomes the thermodynamic constraints and catalyst deactivation challenges of the MDA reaction but also satisfies the requirements for implementation on a commercial scale. As sustainable development of a commercial-scale MDA plant is essential, we further focused on summarizing accomplished reactor modeling and plant-wide economic assessment studies of the MDA process. Based on our analyses, we proposed a conceptual design of a dual-bed circulating microwave membrane fluidized bed reactor as an emerging reactor configuration for the MDA reaction.

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Reaction Fundamentals and Reactor Configuration for Methane Dehydroaromatization: Present State and Future Prospects

Vatankhah,

Shabanian,

Mokhtari

et al. 2024

Energy Fuels

View full text Add to dashboard Cite

show abstract

Aromatics Alkylated with Olefins Utilizing Zeolites as Heterogeneous Catalysts: A Review

Al-Sultani,

Al-Shathr,

Al-Zaidi

2024

Reactions

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The alkylation reaction of aromatic compounds gains considerable attention because of its wide application in bulk and fine chemical production. Aromatics alkylated with olefins is a well-known process, particularly for linear alkylbenzene, phenyloctanes, and heptyltoluene production. As octane boosters and precursors for various petrochemical and bulk chemical products, a wide range of alkylated compounds are in high demand. Numerous unique structures have been proposed in addition to the usual zeolites (Y and beta) utilized in alkylation procedures. The inevitable deactivation of industrial catalysts over time on stream, which is followed by a decrease in catalytic activity and product selectivity, is one of their disadvantages. Therefore, careful consideration of catalyst deactivation regarding the setup and functioning of the process of catalysis is necessary. Although a lot of work has been carried out to date to prevent coke and increase catalyst lifespan, deactivation of the catalyst is still unavoidable. Coke deposition can lead to catalyst deactivation in industrial catalytic processes by obstructing pores and/or covering acid sites. It is very desirable to regenerate inactive catalysts in order to remove the coke and restore catalytic activity at the same time. Depending on the kind of catalyst, the deactivation processes, and the regeneration settings, each regeneration approach has pros and cons. In this comprehensive study, the focus was on discussing the reaction mechanism of 1-octene isomerization and toluene alkylation as an example of isomerization and alkylation reactions that occur simultaneously, shedding light in detail on the catalysts used for this type of complex reaction, taking into account the challenges facing the catalyst deactivation and reactivation procedures.

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Coke Formation and Regeneration during Fe-ZSM-5-Catalyzed Methane Dehydro-Aromatization

Cited by 2 publications

References 34 publications

Reaction Fundamentals and Reactor Configuration for Methane Dehydroaromatization: Present State and Future Prospects

Reaction Fundamentals and Reactor Configuration for Methane Dehydroaromatization: Present State and Future Prospects

Aromatics Alkylated with Olefins Utilizing Zeolites as Heterogeneous Catalysts: A Review

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