Thermal Conductivity of Metastable Ionic Liquid [$C_{2}mim$][$CH_{3}SO_{3}$]

arXiv - PHYS - Chemical Physics Pub Date : 2024-09-10 DOI:arxiv-2409.06346

Daniel Lozano-Martín, Salomé Inês Cardoso Vieira, Xavier Paredes, Maria José Vitoriano Lourenço, Carlos A. Nieto de Castro, Jan V. Sengers, Klemens Massonne

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Abstract

Ionic liquids have been suggested as new engineering fluids, namely in the area of heat transfer, as alternatives to current biphenyl and diphenyl oxide, alkylated aromatics and dimethyl polysiloxane oils, which degrade above 200 {\deg}C and pose some environmental problems. Recently, we have proposed 1-ethyl-3-methylimidazolium methanesulfonate, [$C_{2}mim$][$CH_{3}SO_{3}$], as a new heat transfer fluid, because of its thermophysical and toxicological properties. However, there are some interesting points raised in this work, namely the possibility of the existence of liquid metastability below the melting point (303 K) or second order-disorder transitions ($\lambda$-type) before reaching the calorimetric freezing point. This paper analyses in more detail this zone of the phase diagram of the pure fluid, by reporting accurate thermal-conductivity measurements between 278 and 355 K with an estimated uncertainty of 2% at a 95% confidence level. A new value of the melting temperature is also reported, $T_{melt}$ = 307.8 $\pm$ 1 K. Results obtained support liquid metastability behaviour in the solid-phase region and permit the use of this ionic liquid at a heat transfer fluid at temperatures below its melting point. Thermal conductivity models based on Bridgman theory and estimation formulas were also used in this work, failing to predict the experimental data within its uncertainty.

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可迁移离子液体[$C_{2}mim$][$CH_{3}SO_{3}$]的导热性

有人建议将离子液体作为新的工程液体，即在传热领域，作为目前的联苯和氧化二苯基、烷基芳烃和二甲基聚硅氧烷油的替代品，后者在 200{\deg}C 以上就会降解，并带来一些环境问题。最近，我们提出将 1-乙基-3-甲基咪唑鎓甲烷磺酸盐（[$C_{2}mim$][$CH_{3}SO_{3}$）作为一种新型导热油，因为它具有热物理和毒理学特性。然而，这项工作中也提出了一些有趣的观点，即在熔点（303 K）以下存在液态蜕变的可能性，或在达到热量测定冰点之前存在二阶-二阶蜕变（$\lambda$-type）。本文更详细地分析了纯流体相图的这一区域，报告了在 278 至 355 K 之间的精确热导测量结果，在 95% 的置信水平下，估计不确定性为 2%。所获得的结果支持了固相区的液态蜕变行为，并允许在低于熔点的温度下将这种离子液体用作导热液体。这项工作还使用了基于布里奇曼理论和估计公式的导热模型，但未能在不确定范围内预测实验数据。

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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arXiv - PHYS - Chemical Physics

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