Thermodynamic Properties of Seeds: A Review

C. Tamilarasan, J. Jency, R. Jerlin
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Abstract

Study of isotherms and thermodynamic properties become essential to understand the drying and imbibition mechanisms of seeds. Among post-harvest procedures of seeds, drying is widely known and used in order to assure quality and stability during storage and shelf life. Variation of moisture content through drying is important in order to understand the interaction between water molecules and the seed components, which is the key factor for correct drying and storage. Seed viability could be maintained during long periods owing to their glass structure, as a thermodynamic unstable state, with high viscosity. Thermodynamic properties were enthalpy (Amount of energy available to do work), entropy (Amount of energy present but it not available to do work) and gibbs free energy (Differential energy between the enthalpy and entropy). Thermodynamic properties of seed water determines the reaction kinetics during seed deterioration. Thermodynamic properties showed a critical upper limit, with tolerant species having higher values then susceptible species. In general the values of critical limits of the thermodynamic parameters decreased with increasing temperature. The differential enthalpy and entropy increased in seeds with period of storage and became asymptotic as the seed lost their viability. Thermodynamics properties increased with increase in temperature, indicating that drying and water absorption do not occur spontaneously it requires external energy. A radical drop in germination follows the trend of gibbs free energy increase and enthalpy decrease, indicating intensification of endergonic reaction. Hence, it is concluded that by using thermodynamic properties of seeds the seed quality can be determined without conducting the germination test in shortest period.
种子的热力学性质:综述
研究等温线和热力学特性对于了解种子的干燥和浸泡机制至关重要。在种子收获后的处理过程中,干燥被广泛了解和使用,以确保贮藏和货架期的质量和稳定性。干燥过程中含水量的变化对于了解水分子与种子成分之间的相互作用非常重要,这是正确干燥和贮藏的关键因素。由于种子的玻璃结构是一种热力学不稳定状态,具有较高的粘度,因此可以长期保持种子的活力。热力学性质包括焓(可用于做功的能量)、熵(存在但不可用于做功的能量)和吉布斯自由能(焓和熵之间的差能)。种子水的热力学特性决定了种子变质过程中的反应动力学。热力学性质显示出临界上限,耐受性强的物种的临界值高于易受影响的物种。一般来说,热力学参数的临界值随着温度的升高而降低。种子的差焓和差熵随着贮藏时间的延长而增加,并随着种子失去活力而趋于稳定。热力学特性随温度升高而增加,这表明干燥和吸水不是自发发生的,需要外部能量。发芽率的急剧下降与吉布斯自由能增加和焓降低的趋势一致,表明内能反应加剧。因此,可以得出结论,利用种子的热力学特性可以在最短时间内确定种子质量,而无需进行发芽试验。
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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