The Analytical Scheme on the Inertial Drag for Buoyancy-driven Nanofluid Flow Under Convective Thermal Surface with the Soret Effect

P.K. Pattnaik, Subhajit Panda, S.R. Mishra, Krushna K.P.N. Nayak
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Abstract

Introduction: The two-dimensional mixed convection of nanofluid over a vertical expanding surface is analysed in the current discussion. The expanding surface is embedded in a permeable medium. Methods: In advance, Darcy Forchheimer inertial drag is considered along with the influence of Brownian and thermophoresis, which enriches the study. The novelty of the study is due to the mass concentration along with the role of volume concentration in the flow phenomena. The proposed model is designed in association with a characterizing parameter, which is attained by the use of appropriate similarity conversion. Further, the system of first-order differential equations is resolved by employing a shooting-based numerical method, in particular, the Runge-Kutta fourth-order technique. Results: The simulated results for the said parameters and their behaviour are deployed through graphs and in tabular form. Conclusion: The physical description of each parameter is deliberated briefly. Finally, the important outcomes of the proposed study reported a remarkable hike in the temperature profile that is observed for the enhanced thermophoresis and Brownian motion. Further, the shear rate also increases for the enhanced mixed convection parameter.
考虑Soret效应的对流热表面下浮力驱动纳米流体惯性阻力解析格式
导言:本文分析了纳米流体在垂直膨胀表面上的二维混合对流。所述膨胀表面嵌入可渗透介质中。方法:提前考虑Darcy Forchheimer惯性阻力以及布朗和热泳运动的影响,丰富了研究内容。该研究的新颖之处在于质量浓度与体积浓度在流动现象中的作用。所提出的模型与特征参数相关联,通过使用适当的相似性转换来获得特征参数。此外,采用基于射击的数值方法,特别是龙格-库塔四阶技术,求解了一阶微分方程组。结果:上述参数及其行为的模拟结果通过图形和表格形式进行部署。结论:简要讨论了各参数的物理描述。最后,该研究的重要结果报告了由于热泳动和布朗运动的增强而观察到的温度分布的显著增加。此外,混合对流参数的增强也增加了剪切速率。
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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