预测脂肪酸甲酯混合物氧化性的综合两尺度模型。

Maxime Touffet, Paul Smith, Olivier Vitrac
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引用次数: 1

摘要

石油热氧化的复杂机制及其准确预测长期以来一直受到涉及随机产生的自由基的传播和终止反应的组合性质的阻碍。为了解开这种复杂性,我们提出了一种两尺度的机制描述,将化学功能(尺度1)与这些功能的分子载体(尺度2)联系起来。我们的方法强调了考虑自由基之间的交叉反应的重要性,以便充分理解混合物中的反应性。我们在脂肪酸甲酯(FAME)的二元和三元混合物上严格测试和验证了所提出的双尺度方案,得出了三个关键见解:(1)不稳定质子的提取取决于载体,这与传统上对氢过氧自由基类型的关注背道而驰。(2) 自由基之间的终止反应遵循几何平均定律,表现出对称的碰撞比。(3) 氢过氧化物的分解在80°C以上表现为单分子学过程,挑战了既定的组合范式。适用于宽温度范围(80°C至200°C),我们的发现开启了具有受控热氧化稳定性的混合物的生产,优化了植物油在食品科学、生物燃料和润滑油等应用领域的使用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A comprehensive two-scale model for predicting the oxidizability of fatty acid methyl ester mixtures.

The intricate mechanisms of oil thermooxidation and their accurate prediction have long been hampered by the combinatory nature of propagation and termination reactions involving randomly generated radicals. To unravel this complexity, we suggest a two-scale mechanistic description that connects the chemical functions (scale 1) with the molecular carriers of these functions (scale 2). Our method underscores the importance of accounting for cross-reactions between radicals in order to fully comprehend the reactivities in blends. We rigorously tested and validated the proposed two-scale scheme on binary and ternary mixtures of fatty acid methyl esters (FAMEs), yielding three key insights: (1) The abstraction of labile protons hinges on the carrier, defying the conventional focus on hydroperoxyl radical types. (2) Termination reactions between radicals adhere to the geometric mean law, exhibiting symmetric collision ratios. (3) The decomposition of hydroperoxides emerges as a monomolecular process above 80 °C, challenging the established combinatorial paradigm. Applicable across a wide temperature range (80 °C to 200 °C), our findings unlock the production of blends with controlled thermooxidation stability, optimizing the use of vegetable oils across applications: food science, biofuels, and lubricants.

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