Effective Thermal Conductivity of Cyclohexane-Based Nanofluids Containing Cerium Dioxide Nanoparticles with Chemisorbed Organic Shell

IF 2.5 4区工程技术 Q3 CHEMISTRY, PHYSICAL

International Journal of Thermophysics Pub Date : 2024-12-30 DOI:10.1007/s10765-024-03480-7

Francisco E. Berger Bioucas, Wenchang Wu, Lisa M. S. Stiegler, Wolfgang Peukert, Johannes Walter, Tadafumi Adschiri, Akira Yoko, Thomas M. Koller, Andreas P. Fröba

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Abstract

In the present study, the effective thermal conductivity λ_eff of nanofluids containing metal oxide nanoparticles with a chemisorbed organic shell was investigated experimentally and theoretically. The model systems synthesized by a continuous-flow hydrothermal method consist of cyclohexane as organic base fluid and dispersed nearly spherical cerium dioxide (CeO₂) core nanoparticles with a decanoic acid shell chemically attached to their surface. From the differences between the hydrodynamic diameters of the two core–shell nanoparticle types with (8.6 or 9.1) nm determined by dynamic light scattering (DLS) and the nearly spherical CeO₂ core diameters obtained by analytical ultracentrifugation (AUC) and transmission electron microscopy (TEM), an estimation for the thickness of the entire hydrodynamic layer around the particle core in the range of about (1.1 to 1.3) nm could be deduced. Experimental data for λ_eff of the nanofluids and the thermal conductivity of the base fluid λ_bf were determined with a steady-state guarded parallel-plate instrument (GPPI) with an expanded (k = 2) relative uncertainty of 0.026 at atmospheric pressure over a temperature range from (283.15 to 313.15) K in steps of 10 K. The measurement results for the thermal-conductivity ratio λ_eff ·λ_bf^–1 are independent of temperature and increase with increasing volume fraction of the CeO₂ core nanoparticles up to about 0.023. It was found that the experimental results can be described by the Hamilton–Crosser model within their experimental uncertainties for all temperatures investigated.

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含化学吸附有机壳的二氧化铈纳米环己烷基纳米流体的有效导热性能

本文通过实验和理论研究了化学吸附有机壳的金属氧化物纳米流体的有效导热系数λeff。连续流水热法合成的模型体系由环己烷作为有机底液和分散的近球形二氧化铈（CeO2）核心纳米粒子组成，其表面化学附着有癸酸壳。根据动态光散射（DLS）测定的8.6或9.1 nm的两种核壳纳米颗粒的水动力直径与分析超离心（AUC）和透射电子显微镜（TEM）测定的近球形CeO2芯直径的差异，可以估计出颗粒芯周围整个水动力层的厚度约为1.1 ~ 1.3 nm。在（283.15 ~ 313.15）k温度范围内，以10 k为步长，用稳态保护平行板仪（GPPI）测量了纳米流体的λeff和基液的导热系数λbf的实验数据，其扩展（k = 2）的相对不确定度为0.026。热导率λeff·λbf-1的测量结果与温度无关，且随CeO2纳米颗粒体积分数的增加而增大，最大可达0.023左右。实验结果可以用Hamilton-Crosser模型在实验不确定度范围内描述。

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来源期刊

International Journal of Thermophysics 物理-力学

CiteScore

4.10

自引率

9.10%

发文量

179

审稿时长

5 months

期刊介绍： International Journal of Thermophysics serves as an international medium for the publication of papers in thermophysics, assisting both generators and users of thermophysical properties data. This distinguished journal publishes both experimental and theoretical papers on thermophysical properties of matter in the liquid, gaseous, and solid states (including soft matter, biofluids, and nano- and bio-materials), on instrumentation and techniques leading to their measurement, and on computer studies of model and related systems. Studies in all ranges of temperature, pressure, wavelength, and other relevant variables are included.