Study on the oxidative decomposition mechanism of R1234ye(E): A DFT study

IF 1.7 4区化学 Q3 CHEMISTRY, INORGANIC & NUCLEAR

Journal of Fluorine Chemistry Pub Date : 2024-06-08 DOI:10.1016/j.jfluchem.2024.110309

Biao Feng , Bingrui Wang , Jiachang Wang , Wuwen Chen , Linrui Jian , Zhao Zhang , Dan Wang , Guanjia Zhao , Suxia Ma

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引用次数: 0

Abstract

R1234ye(E) is an environmentally friendly working fluid that can be applied in refrigeration, heat pumps, and organic Rankine cycle systems, but it has issues with oxidative decomposition and flammability. Therefore, based on density functional theory, the oxidative decomposition mechanism of R1234ye(E) has been studied. The results indicate that the oxidative decomposition of R1234ye(E) is a typical chain reaction. The first stage is a chain-initiation reaction, where R1234ye(E) generates a large number of free radicals through initial self thermal decomposition reactions and collision reactions with oxygen. The most likely to occur is path 1–2, which is a homolytic reaction with an energy barrier of only 347.91 kJ/mol. The second stage is the chain-propagation reaction, including the reactions between R1234ye(E) and different free radical and subsequent reactions. The most likely to occur is path 5–1, which is a hydrogen abstraction reaction with an energy barrier of only 21.83 kJ/mol. The last stage is the chain-termination reaction, where the intermediates or products of the above reactions continue to react with the active free radicals until they are consumed. When all the reactants and free radicals are consumed and stable products are generated, the oxidative decomposition reaction ends. The research results provide a reference for the safe application of R1234ye(E) and other HFOs working fluids.

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R1234ye(E) 的氧化分解机理研究：DFT 研究

R1234ye(E) 是一种环保型工作流体，可用于制冷、热泵和有机朗肯循环系统，但它存在氧化分解和易燃性问题。因此，基于密度泛函理论，研究了 R1234ye(E) 的氧化分解机理。结果表明，R1234ye(E) 的氧化分解是一个典型的链式反应。第一阶段是链式引发反应，R1234ye(E) 通过最初的自热分解反应和与氧气的碰撞反应产生大量自由基。最有可能发生的是路径 1-2，这是一种均解反应，其能量势垒仅为 347.91 kJ/mol。第二阶段是链式反应，包括 R1234ye(E) 与不同自由基之间的反应和后续反应。最有可能发生的是路径 5-1，这是一个氢抽取反应，其能量势垒仅为 21.83 kJ/mol。最后一个阶段是链终止反应，上述反应的中间产物或生成物继续与活性自由基发生反应，直至消耗殆尽。当所有的反应物和自由基都被消耗，并生成稳定的产物时，氧化分解反应结束。研究成果为 R1234ye(E) 和其他 HFOs 工作液的安全应用提供了参考。

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来源期刊

Journal of Fluorine Chemistry 化学-无机化学与核化学

CiteScore

3.80

自引率

10.50%

发文量

审稿时长

33 days

期刊介绍： The Journal of Fluorine Chemistry contains reviews, original papers and short communications. The journal covers all aspects of pure and applied research on the chemistry as well as on the applications of fluorine, and of compounds or materials where fluorine exercises significant effects. This can include all chemistry research areas (inorganic, organic, organometallic, macromolecular and physical chemistry) but also includes papers on biological/biochemical related aspects of Fluorine chemistry as well as medicinal, agrochemical and pharmacological research. The Journal of Fluorine Chemistry also publishes environmental and industrial papers dealing with aspects of Fluorine chemistry on energy and material sciences. Preparative and physico-chemical investigations as well as theoretical, structural and mechanistic aspects are covered. The Journal, however, does not accept work of purely routine nature. For reviews and special issues on particular topics of fluorine chemistry or from selected symposia, please contact the Regional Editors for further details.