A DFT-based microkinetic theory for Fe2O3 reduction by CO in chemical looping

IF 5.3 2区 工程技术 Q2 ENERGY & FUELS
Yang Wang, Zhenshan Li
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引用次数: 6

Abstract

Redox kinetics of oxygen carrier in chemical looping is an important component for material preparation, reactor design and process demonstration. How to bridge the gap between the microscale density functional theory (DFT) and the macroscale redox kinetics and develop a first-principle-based theoretical model is still a challenge in the field of chemical looping. This study addresses this challenge and proposes a DFT-based microkinetic rate equation theory to calculate the heterogeneous kinetics of Fe2O3 reduction by CO in chemical looping. Firstly, the DFT calculation is adopted to search the reaction pathways and to obtain the energy barriers of elementary reactions. Secondly, the DFT results are introduced into the transition state theory (TST) to calculate the reaction rate constants and build the rate equations of elementary surface reactions. Finally, by considering the bulk diffusion, a rate equation is developed to bridge the gap between the elementary surface reactions and the grain conversion. In the theory, the reaction mechanism obtained from DFT and kinetic rate constants obtained from TST are directly implemented into the rate equation to predict the reduction kinetics of oxygen carriers without fitting experimental data. The accuracy of the developed theory is validated by experimental data of two Fe2O3 oxygen carriers obtained from the thermogravimetric analyzer (TGA). The microkinetic rate equation theory is based on the first principles calculation and can predict directly the redox kinetics of oxygen carriers without depending on the experimental kinetic data, therefore, it provides a powerful theoretical tool to screen the oxygen carrier materials and optimize the microstructure of oxygen carriers.

化学环中CO还原Fe2O3的dft微动力学理论
化学环中氧载体的氧化还原动力学是材料制备、反应器设计和工艺论证的重要组成部分。如何弥合微观尺度密度泛函理论与宏观尺度氧化还原动力学之间的差距,建立基于第一性原理的理论模型仍然是化学环研究领域面临的挑战。本研究解决了这一挑战,并提出了基于dft的微动力学速率方程理论来计算化学环中CO还原Fe2O3的非均相动力学。首先,采用离散傅立叶变换计算对反应路径进行搜索,得到基本反应的能垒;其次,将DFT结果引入过渡态理论(TST),计算反应速率常数,建立基本表面反应的速率方程。最后,在考虑体扩散的情况下,建立了一个速率方程,以弥补基本表面反应与晶粒转化之间的差距。在理论上,不需要拟合实验数据,直接将DFT得到的反应机理和TST得到的动力学速率常数代入速率方程来预测氧载体的还原动力学。用热重分析仪(TGA)对两种Fe2O3氧载体的实验数据验证了该理论的准确性。微动力学速率方程理论基于第一性原理计算,可以直接预测氧载体的氧化还原动力学,而不依赖于实验动力学数据,为氧载体材料的筛选和氧载体微观结构的优化提供了有力的理论工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Proceedings of the Combustion Institute
Proceedings of the Combustion Institute 工程技术-工程:化工
CiteScore
7.00
自引率
0.00%
发文量
420
审稿时长
3.0 months
期刊介绍: The Proceedings of the Combustion Institute contains forefront contributions in fundamentals and applications of combustion science. For more than 50 years, the Combustion Institute has served as the peak international society for dissemination of scientific and technical research in the combustion field. In addition to author submissions, the Proceedings of the Combustion Institute includes the Institute''s prestigious invited strategic and topical reviews that represent indispensable resources for emergent research in the field. All papers are subjected to rigorous peer review. Research papers and invited topical reviews; Reaction Kinetics; Soot, PAH, and other large molecules; Diagnostics; Laminar Flames; Turbulent Flames; Heterogeneous Combustion; Spray and Droplet Combustion; Detonations, Explosions & Supersonic Combustion; Fire Research; Stationary Combustion Systems; IC Engine and Gas Turbine Combustion; New Technology Concepts The electronic version of Proceedings of the Combustion Institute contains supplemental material such as reaction mechanisms, illustrating movies, and other data.
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