Mathematical modelling of the vitamin C clock reaction: a study of two kinetic regimes

Aliya Alsaleh, David J. Smith, Sara Jabbari
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Abstract

Chemically reacting systems exhibiting a repeatable delay period before a visible and sudden change are referred to as clock reactions; they have a long history in education and provide an idealisation of various biochemical and industrial processes. We focus on a purely substrate-depletive clock reaction utilising vitamin C, hydrogen peroxide, iodine and starch. Building on a recent study of a simplified two-reaction model under high hydrogen peroxide concentrations, we develop a more detailed model which breaks the slow reaction into two steps, one of which is rate-limiting unless hydrogen peroxide levels are very high. Through asymptotic analysis, this model enables the effect of hydrogen peroxide concentration to be elucidated in a principled way, resolving an apparent discrepancy with earlier literature regarding the order of the slow reaction kinetics. The model is analysed in moderate- and high-hydrogen peroxide regimes, providing approximate solutions and expressions for the switchover time which take into account hydrogen peroxide concentration. The solutions are validated through simultaneously fitting the same set of parameters to several experimental series, then testing on independent experiments across widely varying hydrogen peroxide concentration. The study thereby presents and further develops a validated mechanistic understanding of a paradigm chemical kinetics system.
维生素 C 时钟反应的数学建模:两种动力学机制的研究
化学反应系统在发生明显的突变之前会出现一个可重复的延迟期,这种反应被称为时钟反应;时钟反应在教育领域有着悠久的历史,是各种生物化学和工业过程的理想化产物。我们将重点放在利用维生素 C、过氧化氢、碘和淀粉的纯底物消耗性时钟反应上。在最近对高过氧化氢浓度下的简化双反应模型研究的基础上,我们建立了一个更详细的模型,该模型将缓慢反应分成两个步骤,除非过氧化氢浓度非常高,否则其中一个步骤将限制反应速率。通过渐近分析,该模型能够以一种原则性的方式阐明过氧化氢浓度的影响,解决了与早期文献中关于缓慢反应动力学顺序的明显差异。该模型在中度和高度过氧化氢条件下进行了分析,提供了考虑到过氧化氢浓度的切换时间近似解和表达式。通过对多个实验序列同时拟合同一组参数,然后在不同过氧化氢浓度的独立实验中进行测试,验证了这些解决方案。因此,该研究提出并进一步发展了对典型化学动力学系统的有效机理理解。
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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