不使用WLF方程模拟温度对生物聚合物和食品玻璃化转变的影响

IF 5.3 2区 农林科学 Q1 FOOD SCIENCE & TECHNOLOGY
Micha Peleg
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引用次数: 0

摘要

传统上,温度对食品中生化反应和生物过程速率的影响,以及对包括食品在内的生物聚合物机械性能的影响,都是用阿伦尼乌斯方程来描述的,该方程只有一个可调参数,即“活化能”。在过去的三十年中,该模型经常被WLF方程所取代,该方程借鉴自聚合物科学,具有两个可调参数,因此更适合实验数据。结果表明,WLF模型(以及VTF模型)与阿伦尼乌斯方程的扩展版本相同,其中绝对温度被可调节的参考温度取代。这两个版本都意味着,描述过程或反应速率随温度上升或粘度或模量随温度下降的曲线在玻璃化转变温度Tg上下必须具有相同的特征上凹度,无论如何定义和确定。然而,至少一些记录在过渡区或其周围的实验数据表明并非如此,在某些情况下甚至显示出凹方向反转。这种关系的数学描述需要不同种类的温度依赖模型,并描述了两种这样的替代方案。还提出了两种不同的方法来表示温度作为一个无量纲的自变量,使不同的转变模式在同一图表中可以合并和比较。所描述的方法纯粹是形式主义的;没有合适的考虑被调用,两个模型都没有声称是排他性的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

On Modeling the Temperature Effects on Biopolymers and Foods Undergoing Glass Transition without the WLF Equation

On Modeling the Temperature Effects on Biopolymers and Foods Undergoing Glass Transition without the WLF Equation

Traditionally, the effect of temperature on the rate of biochemical reactions and biological processes in foods, and on the mechanical properties of biopolymers including foods, has been described by the Arrhenius equation which has a single adjustable parameter, namely the “energy of activation.” During the last three decades, this model has been frequently replaced by the WLF equation, borrowed from Polymer Science, which has two adjustable parameters and hence better fit to experimental data. It is demonstrated that the WLF model (and hence also the VTF model) is identical to an expanded version of the Arrhenius equation where the absolute temperature is replaced by an adjustable reference temperature. Both versions imply that the curve describing a process or reaction’s rate rise with temperature or the viscosity or modulus drop with temperature must have the same characteristic upper concavity above and below the glass transition temperature, Tg, however it is defined and determined. Nevertheless, at least some reported experimental data recorded at or around the transition regime suggest otherwise and in certain cases even show concavity direction inversion. The mathematical description of such relationships requires different kinds of temperature-dependence models, and two such alternatives are described. Also suggested are two different ways to present the temperature as a dimensionless independent variable which enables to lump and compare different transition patterns in the same graph. The described approach is purely formalistic; no fit considerations are invoked and neither model is claimed to be exclusive.

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来源期刊
Food Engineering Reviews
Food Engineering Reviews FOOD SCIENCE & TECHNOLOGY-
CiteScore
14.20
自引率
1.50%
发文量
27
审稿时长
>12 weeks
期刊介绍: Food Engineering Reviews publishes articles encompassing all engineering aspects of today’s scientific food research. The journal focuses on both classic and modern food engineering topics, exploring essential factors such as the health, nutritional, and environmental aspects of food processing. Trends that will drive the discipline over time, from the lab to industrial implementation, are identified and discussed. The scope of topics addressed is broad, including transport phenomena in food processing; food process engineering; physical properties of foods; food nano-science and nano-engineering; food equipment design; food plant design; modeling food processes; microbial inactivation kinetics; preservation technologies; engineering aspects of food packaging; shelf-life, storage and distribution of foods; instrumentation, control and automation in food processing; food engineering, health and nutrition; energy and economic considerations in food engineering; sustainability; and food engineering education.
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