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预测骨架和烃结构对沸石催化的β-断裂反应的影响。

Predicting the effect of framework and hydrocarbon structure on the zeolite-catalyzed beta-scission.

作者信息

Ureel Yannick, Alexopoulos Konstantinos, Van Geem Kevin M, Sabbe Maarten K

机构信息

Laboratory for Chemical Technology, Department of Materials, Textiles and Chemical Engineering, Ghent University Technologiepark 125 9052 Gent Belgium

Department of Chemical Engineering, Pennsylvania State University University Park Pennsylvania 16802-1503 USA

出版信息

Catal Sci Technol. 2024 Oct 15;14(24):7020-7036. doi: 10.1039/d4cy00973h. eCollection 2024 Dec 9.

DOI:10.1039/d4cy00973h
PMID:39421599
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11474451/
Abstract

Developing improved zeolites is essential in novel sustainable processes such as the catalytic pyrolysis of plastic waste. This study used density functional theory to investigate how alkyl chain length, unsaturated bonds, and branching affect β-scission kinetics in four zeolite frameworks, a key reaction in hydrocarbon cracking. The activation enthalpy was evaluated for a wide variety of 23 hydrocarbons, with 6 to 12 carbon atoms, in FAU, MFI, MOR, and TON. The consideration of both branched and linear olefin and diolefin reactants for the β-scission indicates how the reactant structure influences the intrinsic cracking kinetics, which is especially relevant for the catalytic cracking of plastic waste feedstocks. Intrinsic chemical effects, such as resonance stabilization, the inductive effect, and pore stabilization were found to provide an essential contribution to the activation enthalpy. Additionally, a predictive group additive model incorporating a novel so-called "pore confinement descriptor" was developed for fast prediction of the β-scission activation barrier of a wide range of molecules in the four zeolites. The obtained model can serve as an input for detailed kinetic models in zeolite-catalyzed cracking reactions. The acquired fundamental insights in the cracking of hydrocarbons, relevant for renewable feedstocks, correspond well with experimental observations and will facilitate an improved rational zeolite design.

摘要

开发性能更优的沸石对于新型可持续工艺至关重要,比如塑料垃圾的催化热解。本研究运用密度泛函理论,探究了烷基链长度、不饱和键和支化如何影响四种沸石骨架中的β-断裂动力学,这是烃类裂解中的一个关键反应。对FAU、MFI、MOR和TON这四种沸石中23种含6至12个碳原子的多种烃类的活化焓进行了评估。考虑支链和直链烯烃及二烯烃反应物的β-断裂,表明反应物结构如何影响本征裂解动力学,这对于塑料垃圾原料的催化裂解尤为重要。发现诸如共振稳定、诱导效应和孔道稳定等本征化学效应,对活化焓有重要贡献。此外,还开发了一种包含新型所谓“孔道限制描述符”的预测性基团加和模型,用于快速预测四种沸石中多种分子的β-断裂活化能垒。所得模型可作为沸石催化裂解反应详细动力学模型的输入。在与可再生原料相关的烃类裂解方面获得的基本见解,与实验观察结果非常吻合,并将有助于改进合理的沸石设计。

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