Rational Design of Zinc/Zeolite Catalyst: Selective Formation of <i>p</i>‐Xylene from Methanol to Aromatics Reaction

Wang, Ning; Li, Jing; Sun, Wenjing; Hou, Yilin; Zhang, Lan; Hu, Xiaomin; Yang, Yong; Xiao, Chen; Chen, Congmei; Chen, Biaohua; Qian, Weizhong

doi:10.1002/anie.202114786

Cited by 28 publications

(12 citation statements)

References 53 publications

(8 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Combined with the difference of the acid type between SNZ-60 and NZ-240, the difference of aromatic selectivity further indicated that the high density of LAS on SNZ-60 played a positive role during the aromatic production. The introduction of Zn species could consume part of BAS on the surface, and the new generated Zn-LAS could obviously promote the dehydrogenation aromatization process of alkenes, the selectivity of total aromatics, and BTX could increase from 25.6 and 14.1% to 34.5 and 18% of NZ-60, respectively . In addition, the selectivity of light alkanes was significantly decreased from 27 to 19%.…”

Section: Resultsmentioning

confidence: 99%

Synergistic Catalysis of Brønsted Acid, Al-Lewis Acid, and Zn-Lewis Acid on Steam-Treated Zn/ZSM-5 for Highly Stable Conversion of Methanol to Aromatics

Cao

Zhang

et al. 2023

Ind. Eng. Chem. Res.

View full text Add to dashboard Cite

The development of stable and selective ZSM-5 catalysts for methanol aromatization remains an ongoing challenge. Here, we demonstrate highly stable aromatization on ZSM-5 by preliminary steam treatment before Zn introduction. Steam treatment destroyed part of frameworks, which decreased acid density from 0.5 to 0.25 mmol g −1 and increased Al-Lewis acid sites (Al-LAS) at the expense of Brønsted acid sites (BAS). However, aromatization activity was further increased and the lifetime was still kept at 100 h. A comparative experiment found that increasing the SiO 2 /Al 2 O 3 ratio from 60 to 240 also decreased acid density to 0.25 mmol g −1 , but BAS-based acid sites aggravated coke formation and reduced lifetime to 50 h. This reflected that Al-LAS and BAS on steam-treated ZSM-5 provided synergistic catalysis for stable aromatization. Introducing Zn into steamtreated ZSM-5 further transformed part of BAS to Zn-LAS but not changed acid density, which determined increased aromatics selectivity and a quite different well-maintained stability.

show abstract

Section: Resultsmentioning

confidence: 99%

Synergistic Catalysis of Brønsted Acid, Al-Lewis Acid, and Zn-Lewis Acid on Steam-Treated Zn/ZSM-5 for Highly Stable Conversion of Methanol to Aromatics

Cao

Zhang

et al. 2023

Ind. Eng. Chem. Res.

View full text Add to dashboard Cite

show abstract

“…Zeolitic core–shell structures often provide versatile beneficial functions for catalysis, , for instance, shape selectivity, , bifunctionality, and sintering resistance. , Rimer et al have developed abundant types of core–shell and egg-shell zeolite catalysts that showed enhanced performance in hydrocarbon processing as well as biomass conversion. , Very recently, the core–shell zeolite has also been reported for CO 2 conversion, primarily for the regulation of the selectivity of aromatic products. , Herein, we report that such a core–shell zeolite structure was able to overcome the challenges aforementioned during CO 2 hydrogenation, where the construction of the shell, referring to coating a layer of silicalite-1 (S-1) over a pristine zeolite H-ZSM-5 crystal, was realized by a facile secondary growth. Such an S-1 shell was found to be able to secure the bifunctional nature of a typical CO 2 hydrogenation catalyst, i.e ., In 2 O 3 /H-ZSM-5, by which the activity for the synthesis of C 2 + hydrocarbons under both nanoscale (in a manner of PM) and microscale (in a manner of GM) proximity was well-improved.…”

Section: Introductionmentioning

confidence: 82%

“…Additionally, zeolite coking could be another potential deactivation factor for such an MTH-involved bifunctional catalysis process in practical application scenarios, 31,38 although during CO 2 hydrogenation, long-term (∼100 h) stability was usually observed in lab-scale research. 18,27 Zeolitic core−shell structures often provide versatile beneficial functions for catalysis, 39,40 for instance, shape selectivity, 41,42 bifunctionality, 43 and sintering resistance. 44,45 Rimer et al have developed abundant types of core−shell and egg-shell zeolite catalysts that showed enhanced performance in hydrocarbon processing as well as biomass conversion.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Zeolitic core–shell structures often provide versatile beneficial functions for catalysis, 39 , 40 for instance, shape selectivity, 41 , 42 bifunctionality, 43 and sintering resistance. 44 , 45 Rimer et al have developed abundant types of core–shell and egg-shell zeolite catalysts that showed enhanced performance in hydrocarbon processing as well as biomass conversion.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Silicalite-1 Layer Secures the Bifunctional Nature of a CO₂ Hydrogenation Catalyst

Xing

Turner

et al. 2023

JACS Au

View full text Add to dashboard Cite

Close proximity usually shortens the travel distance of reaction intermediates, thus able to promote the catalytic performance of CO 2 hydrogenation by a bifunctional catalyst, such as the widely reported In 2 O 3 /H-ZSM-5. However, nanoscale proximity (e.g., powder mixing, PM) more likely causes the fast deactivation of the catalyst, probably due to the migration of metals (e.g., In) that not only neutralizes the acid sites of zeolites but also leads to the reconstruction of the In 2 O 3 surface, thus resulting in catalyst deactivation. Additionally, zeolite coking is another potential deactivation factor when dealing with this methanol-mediated CO 2 hydrogenation process. Herein, we reported a facile approach to overcome these three challenges by coating a layer of silicalite-1 (S-1) shell outside a zeolite H-ZSM-5 crystal for the In 2 O 3 /H-ZSM-5-catalyzed CO 2 hydrogenation. More specifically, the S-1 layer (1) restrains the migration of indium that preserved the acidity of H-ZSM-5 and at the same time (2) prevents the over-reduction of the In 2 O 3 phase and (3) improves the catalyst lifetime by suppressing the aromatic cycle in a methanol-to-hydrocarbon conversion step. As such, the activity for the synthesis of C 2 + hydrocarbons under nanoscale proximity (PM) was successfully obtained. Moreover, an enhanced performance was observed for the S-1-coated catalyst under microscale proximity (e.g., granule mixing, GM) in comparison to the S-1-coating-free counterpart. This work highlights an effective shielding strategy to secure the bifunctional nature of a CO 2 hydrogenation catalyst.

show abstract

“…Studies of the MTP process have shown that small-pore zeolites with weak acidity show promise as catalysts for the olefin-based catalytic cycle and can increase the propene yield. The MTA process can also efficiently produce aromatics [148,149] that are very important platform molecules for high-value commodity chemicals [150] . Although the MTA reaction was not addressed in detail in this review, highly acidic zeolites having large pore channels may be able to promote this reaction based on prior research regarding the dual cycle mechanism.…”

Section: Discussionmentioning

confidence: 99%

Fundamentals of the catalytic conversion of methanol to hydrocarbons

Liu¹,

Huang²

2022

Chem Synth

View full text Add to dashboard Cite

For more than four decades, the methanol-to-hydrocarbons (MTH) reaction has been a successful route to producing valuable fuels and chemicals from non-petroleum feedstocks. This review provides the most comprehensive summary to date of recent research concerning the mechanistic fundamentals of this important reaction, covering different reaction stages. Mechanisms that have been proposed to explain the initial C-C bond formation during the induction stage of the MTH reaction are introduced, including the methoxymethyl cation, Koch carbonylation, carbene and methane-formaldehyde processes. At present, there is no consensus regarding these hypothetical mechanisms as a consequence of the limited amount of conclusive experimental evidence. The steady state of the MTH reaction is also examined with a focus on the widely accepted indirect hydrocarbon pool mechanism and the dual cycle concept that provides a mechanistic basis for the effects of zeolite structures and reaction conditions on product distribution. In the following section, advanced characterization techniques capable of providing new insights into the formation of coke species during the MTH reaction and innovative approaches effectively inhibiting coke formation are introduced. Finally, a summary is provided and perspectives on current challenges and the future development of this area are presented.

show abstract

Rational Design of Zinc/Zeolite Catalyst: Selective Formation of p‐Xylene from Methanol to Aromatics Reaction

Cited by 28 publications

References 53 publications

Synergistic Catalysis of Brønsted Acid, Al-Lewis Acid, and Zn-Lewis Acid on Steam-Treated Zn/ZSM-5 for Highly Stable Conversion of Methanol to Aromatics

Synergistic Catalysis of Brønsted Acid, Al-Lewis Acid, and Zn-Lewis Acid on Steam-Treated Zn/ZSM-5 for Highly Stable Conversion of Methanol to Aromatics

Silicalite-1 Layer Secures the Bifunctional Nature of a CO₂ Hydrogenation Catalyst

Fundamentals of the catalytic conversion of methanol to hydrocarbons

Contact Info

Product

Resources

About

Rational Design of Zinc/Zeolite Catalyst: Selective Formation of p‐Xylene from Methanol to Aromatics Reaction

Cited by 28 publications

References 53 publications

Synergistic Catalysis of Brønsted Acid, Al-Lewis Acid, and Zn-Lewis Acid on Steam-Treated Zn/ZSM-5 for Highly Stable Conversion of Methanol to Aromatics

Synergistic Catalysis of Brønsted Acid, Al-Lewis Acid, and Zn-Lewis Acid on Steam-Treated Zn/ZSM-5 for Highly Stable Conversion of Methanol to Aromatics

Silicalite-1 Layer Secures the Bifunctional Nature of a CO2 Hydrogenation Catalyst

Fundamentals of the catalytic conversion of methanol to hydrocarbons

Contact Info

Product

Resources

About

Silicalite-1 Layer Secures the Bifunctional Nature of a CO₂ Hydrogenation Catalyst