Sulfonic acid-modified MOFs as heterogeneous bifunctional catalysts for ethylene oligomerization at room temperature without cocatalysts

Ethylene oligomerization plays an important role in industrial production. However, when taking the traditional non-metallocene catalysts and MOF catalysts for ethylene oligomerization, they typically require methylaluminoxane (MAO), aluminum alkyl, and other cocatalysts, which is neither environmen...

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Published in:Catalysis science & technology 2024-10, Vol.14 (21), p.627-6277
Main Authors: Ning, Yao, Yang, Yuqi, Shan, Dongming, Mei, Shuxing, Yan, Yibai, Ding, Linjie, Zhang, Ying
Format: Article
Language:English
Subjects:
Acids
Catalysts
Ethylene
Lewis acid
Metal clusters
Metal-organic frameworks
Oligomerization
Production costs
Room temperature
Sulfonic acid
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Summary:Ethylene oligomerization plays an important role in industrial production. However, when taking the traditional non-metallocene catalysts and MOF catalysts for ethylene oligomerization, they typically require methylaluminoxane (MAO), aluminum alkyl, and other cocatalysts, which is neither environmentally friendly nor helpful in reducing production costs. Here, three sulfonic acid-modified MOFs (SA/MIL-101(Cr), UiO-66-NS and MIL-101(Cr)-NS) were prepared and used as catalysts for ethylene oligomerization at room temperature without using any cocatalysts. All of them exhibited excellent catalytic performances ( e.g. , 10SA/MIL-101(Cr), 21 953 g mol Cr −1 h −1 , with C 8 selectivity greater than 70.32%), and their oligomerization activity increased by almost tenfold compared to unmodified MOFs. The presence of Lewis acid (L acid) and Brønsted acid (B acid) sites in modified MOFs is the key to improved performances. In particular, the presence of B acid weakens the role of metal clusters and ligands in MOFs, making it easier for metal centers to bind to ethylene molecules for further oligomerization. This work first demonstrates that bifunctional MOF catalysts can catalyze ethylene tetramerization under mild conditions without cocatalysts. Ethylene oligomerization plays an important role in industrial production.
ISSN:2044-4753
2044-4761
DOI:10.1039/d4cy00502c