Electrofreezing of the phase-change material CaCl2•6H2O and its impact on supercooling and the nucleation time

I. Sutjahja, A. F. M. Moshiur Rahman, R. Putri, A. Swandi, R. Anggraini, S. Wonorahardjo, D. Kurnia, S. Wonorahardjo
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引用次数: 5

Abstract

This paper reports electrofreezing experiments on the inorganic phase-change material (PCM) CaCl2?6H2O by using an insulated copper electrode that is commonly sold in the market. The effect of the applied voltage or electric field to the nucleation process is measured by the nucleation temperature, freezing temperature, supercooling degree, induction time, time for supercooling, and time for crystallisation. It is found that, compared to the zero field, the freezing temperature remains nearly constant while the nucleation temperature increases with increasing applied field, leading to a reduction in the supercooling degree. The decrease in the supercooling degree is approximately 6 K for an applied voltage of V = 5.0 kV or E = 107 V m-1. With the increase in the applied field the induction time decreased considerably along with reduction of the measured data spread as compared to the no-voltage case, while the crystallisation time for the phase transformation prolonged. The overall phenomena are analysed in terms of modification of the Gibbs free energy for crystallisation owing to the applied field, with the mechanism involving bubble generation and formation of a copper-chloride complex.
相变材料CaCl2•6H2O的电冷冻及其对过冷和成核时间的影响
本文报道了无机相变材料(PCM) CaCl2?6H2O通过使用绝缘铜电极,通常在市场上出售。施加电压或电场对成核过程的影响是通过成核温度、冻结温度、过冷度、感应时间、过冷时间和结晶时间来测量的。结果表明,与零场相比,随着施加磁场的增大,凝固温度基本保持不变,而成核温度则升高,导致过冷度降低。当施加电压V = 5.0 kV或E = 107 V m-1时,过冷度降低约6 K。与无电压情况相比,随着施加电场的增加,感应时间大大减少,测量数据的传播也减少,而相变的结晶时间延长。从吉布斯自由能的结晶变化的角度分析了整个现象,其机制涉及气泡的产生和氯化铜络合物的形成。
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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