Your search keyword '"Zhu, Wenliang"' showing total 5 results

1. Highly Selective Carbonylation of CH3Cl to Acetic Acid Catalyzed by Pyridine‐Treated MOR Zeolite.

Author

Fang, Xudong, Wen, Fuli, Ding, Xiangnong, Liu, Hanbang, Chen, Zhiyang, Liu, Zhaopeng, Liu, Hongchao, Zhu, Wenliang, and Liu, Zhongmin

Subjects

*ACETIC acid, *CARBONYLATION, *METHOXY group, *ZEOLITES, *ZEOLITE catalysts, *METHYL acetate

Abstract

The selective conversion of methane to high value‐added chemicals under mild conditions is of great significance for the commercially viable and sustainable utilization of methane but remains a formidable challenge. Herein, we report a strategy for efficiently converting methane to acetic acid via CH3Cl as an intermediate. Up to 99.3 % acetic acid and methyl acetate (AA+MA) selectivity was achieved over pyridine‐pretreated MOR (MOR‐8) under moderate conditions of 523 K and 2.0 MPa. Water, conventionally detrimental to carbonylation reaction over zeolite catalysts, was conducive to the production of AA in the current reaction system. In the 100 h continuous test with the MOR‐8 catalyst, the average AA+MA selectivity remained over 98 %. AA was formed by carbonylation of methoxy groups within 8‐membered rings of MOR followed by hydrolysis. This strategy provided an approach for highly efficient utilization of methane to oxygenates under mild reaction conditions. [ABSTRACT FROM AUTHOR]

Published

2022

2. Highly Enhanced Aromatics Selectivity by Coupling of Chloromethane and Carbon Monoxide over H‐ZSM‐5.

Author

Fang, Xudong, Liu, Hongchao, Chen, Zhiyang, Liu, Zhaopeng, Ding, Xiangnong, Ni, Youming, Zhu, Wenliang, and Liu, Zhongmin

Subjects

*CARBON monoxide, *METHYL chloride, *HYDROGEN transfer reactions, *ACETYL group, *SUSTAINABLE chemistry

Abstract

The transformation of methane into high value‐added chemicals such as aromatics provides a more desired approach towards sustainable chemistry but remains a critical challenge due to the low selectivity of aromatics and poor stability. Herein, we first report a coupling reaction of CH3Cl and CO (CCTA) based on methane conversion, which achieves extremely high aromatics selectivity (82.2 %) with the selectivity of BTX up to ca. 60 % over HZSM‐5. The promoting effects have been demonstrated on other zeolites especially 10‐membered rings (10 MR) zeolites. Multiple characterizations show that 2,3‐dimethyl‐2‐cyclopentene‐1‐one (DMCPO) is generated from acetyl groups and olefins. Furthermore, isotopic labeling analysis confirms that CO is inserted into the DMCPO and aromatics rings. A new aromatization mechanism is proposed, including the formation of the above intermediates, which conspicuously weakens the hydrogen transfer reaction, leading to a considerable increase of aromatics selectivity and a dramatic drop in alkanes. [ABSTRACT FROM AUTHOR]

Published

2022

3. The Formation of Percolative Composites with a High Dielectric Constant and High Conductivity.

Author

Wang, Mingsong, Zhu, Jiliang, Zhu, Wenliang, Zhu, Bo, Liu, Jing, Zhu, Xiaohong, Pu, Yunti, Sun, Ping, Zeng, Zifan, Li, Xuhai, Yuan, Daqing, Zhu, Shengyun, and Pezzotti, Giuseppe

Published

2012

4. Coupling of Methanol and Carbon Monoxide over H‐ZSM‐5 to Form Aromatics.

Author

Chen, Zhiyang, Ni, Youming, Zhi, Yuchun, Wen, Fuli, Zhou, Ziqiao, Wei, Yingxu, Zhu, Wenliang, and Liu, Zhongmin

Subjects

*CARBON monoxide, *CHEMICAL reactions, *HYDROGENATION, *ACTIVATED carbon, *CATALYSTS

Abstract

Abstract: The conversion of methanol into aromatics over unmodified H‐ZSM‐5 zeolite is generally not high because the hydrogen transfer reaction results in alkane formation. Now circa 80 % aromatics selectivity for the coupling reaction of methanol and carbon monoxide over H‐ZSM‐5 is reported. Carbonyl compounds and methyl‐2‐cyclopenten‐1‐ones (MCPOs), which were detected in the products and catalysts, respectively, are considered as intermediates. The latter species can be synthesized from the former species and olefins. 13C isotope tracing and 13C liquid‐state NMR results confirmed that the carbon atoms of CO molecules were incorporated into MCPOs and aromatic rings. A new aromatization mechanism that involves the formation of the above intermediates and co‐occurs with a dramatically decreased hydrogen transfer reaction is proposed. A portion of the carbons in CO molecules are incorporated into aromatic, which is of great significance for industrial applications. [ABSTRACT FROM AUTHOR]

Published

2018

5. Innenrücktitelbild: Highly Enhanced Aromatics Selectivity by Coupling of Chloromethane and Carbon Monoxide over H‐ZSM‐5 (Angew. Chem. 13/2022).

Author

Fang, Xudong, Liu, Hongchao, Chen, Zhiyang, Liu, Zhaopeng, Ding, Xiangnong, Ni, Youming, Zhu, Wenliang, and Liu, Zhongmin

Subjects

*CARBON monoxide, *METHYL chloride

Abstract

Innenrücktitelbild: Highly Enhanced Aromatics Selectivity by Coupling of Chloromethane and Carbon Monoxide over H-ZSM-5 (Angew. Keywords: Aromatics; Carbon Monoxide; Chloromethane; HZSM-5; Methane Conversion EN Aromatics Carbon Monoxide Chloromethane HZSM-5 Methane Conversion 1 1 1 03/16/22 20220321 NES 220321 B Die Kupplung von CH SB 3 sb Cl mit CO b über H-Zeolithen ist eine effiziente Reaktion für die Umwandlung von Methan in Aromaten, die die nachhaltige Entwicklung von Erdgas auf einem umweltfreundlichen Weg gewährleistet. Methane Conversion, Aromatics, Carbon Monoxide, Chloromethane, HZSM-5. [Extracted from the article]

Published

2022