MHD free convective heat and mass transfer flow passing through semi‐infinite plate for Cu‐water and TiO2‐water nanofluids in presence of radiation embedded in porous medium

Kangkan Choudhury, Sweety Sharma
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Abstract

This research presents an analytical study of magnetohydrodynamics (MHD)‐free convective heat and mass transfer flow of a nanofluid bounded by a semi‐infinite flat plate. A magnetic field of strength is applied throughout the fluid region. The plate is moving with a constant velocity , temperature, and the concentration are assumed to be fluctuating with time harmonically from a constant mean at the plate. The frontier equations are assumed to be of an oscillatory nature and cracked analytically using the perturbation technique. The novelty of the present work is to examine the heat and mass transfer MHD flow for Cu‐water and TiO2‐water nanofluids in the presence of thermal radiation. The influence of physical parameters on the flow domain is described in the discussions by graphically and in tabular form. It was found that the fluid temperature and skin friction were reduced with the increased values of the radiation parameters for Cu‐water and TiO2‐water nanofluids. Also, it is noticed that the concentration boundary layer thickness decreases with an increase in chemical reaction parameters.
多孔介质中嵌入的铜-水和 TiO2-水纳米流体在辐射作用下通过半无限板的 MHD 自由对流传热和传质流动
本研究介绍了对以半无限平板为边界的纳米流体的磁流体力学(MHD)无对流传热和传质流动的分析研究。在整个流体区域都施加了一定强度的磁场。假设平板以恒定速度运动,温度和浓度从平板上的恒定平均值随时间谐波波动。假设前沿方程具有振荡性质,并使用扰动技术进行分析破解。本研究的新颖之处在于研究了存在热辐射的铜-水和二氧化钛-水纳米流体的传热和传质 MHD 流动。讨论以图表形式描述了物理参数对流域的影响。研究发现,随着辐射参数值的增加,铜-水和二氧化钛-水纳米流体的流体温度和表皮摩擦都有所降低。此外,还发现浓度边界层厚度随着化学反应参数的增加而减小。
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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