催化作用
选择性
烯烃纤维
碳氢化合物
化学
烷烃
丁烯
氧气
丁烷
串联
焦炭
热液循环
碳纤维
无机化学
烯烃
光化学
化学工程
活性炭
工作(物理)
甲烷
氧合物
反应条件
丙烷
产量(工程)
有机化学
作者
Siyu Chen,Zhiwei Liang,Zhendong Feng,Zhaochi Feng,Shan Tang,Zelong Li,Jijie Wang,Can Li
出处
期刊:Angewandte Chemie
[Wiley]
日期:2025-09-30
卷期号:64 (46): e202512845-e202512845
被引量:3
标识
DOI:10.1002/anie.202512845
摘要
Abstract Recycling CO 2 to light olefins (C 2 ‐ C 4 ) is a promising strategy for long‐term carbon storage. However, selective hydrogenation to light olefins while suppressing alkane formation remains a challenge. This work presents an optimized ZnZrO x /SAPO‐18 tandem catalyst, which achieves 88.7% light olefins selectivity at 9.5% CO 2 conversion with C 3 +C 4 dominating 68.4% of the hydrocarbons. The catalyst exhibits resistance to over hydrogenation, yielding the (C 2 −C 4 )/(C 2 0 −C 4 0 ) (O/P) ratio of 17.7 and only 1.4% CH 4 selectivity. Furthermore, the catalyst shows good stability over 100 h on stream without obvious deactivation, owing to the synergistic effect between ZnZrO x and the reaction conditions, which facilitates the elimination of coke deposition. Hydrothermal treatment brings more Zn─O─Zr active sites and oxygen vacancies (O v ) on ZnZrO x , as well as the modulated Brønsted acid sites (BAS) in SAPO‐18 suppresses the over‐hydrogenation of olefins, and the AEI‐type cage can contain expanded hydrocarbon pool (HCP) intermediates for enhanced C 3 +C 4 formation. This study advances the development of selective CO 2 ‐to‐olefin conversion technologies.
科研通智能强力驱动
Strongly Powered by AbleSci AI