Chemical reaction effect across the moving flat plate with heat generation and MHD flow of Maxwell fluid with viscous dissipation

IF 2.6 4区 物理与天体物理 Q2 PHYSICS, APPLIED
K. Sudarmozhi, D. Iranian, Ilyas Khan
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Abstract

In this paper, the investigation centered on examining a Maxwell fluid’s convective double diffusive flow carefully considers factors such as chemical reactions, radiation, and the presence of a permeable moving flat plate. Additionally, the study encompassed the effects of heat generation and magnetohydrodynamics (MHD). The governing equations, initially expressed as partial differential equations, were converted into ordinary differential equations using a similarity transformation technique to facilitate the analysis. The computational power of MATLAB’s BVP4C software was harnessed to solve this resultant system of ODEs efficiently. The outcomes of this investigation were presented in the form of graphical representations that vividly depicted the behavior of the flow field, energy conservation, and concentration profiles under various parameter combinations. The research findings were thoughtfully summarized in a table, offering a comprehensive overview of temperature, velocity, and mass profiles across various parameters. These parameters included the Deborah number, chemical reaction rate, Eckert number, Lewis number, Prandtl number, porosity parameter, and MHD parameter. A notable discovery emerging from this study was the inverse relationship observed between nondimensional concentration contours and the magnitude of the chemical reaction rate. Simultaneously, it was observed that higher values of the Maxwell fluid led to a rise in the thickness of the temperature boundary layer. These findings offer valuable insights into the intricate interplay of physical and chemical phenomena in convective flows involving complex fluid properties and boundary conditions. The temperature outline diminishes as the heat generation rate increases, while the concentration profile declines with an elevation in the chemical reaction rate.

带发热的移动平板上的化学反应效应和带粘性耗散的麦克斯韦流体的 MHD 流动
在本文中,调查的中心是研究麦克斯韦流体的对流双扩散流,仔细考虑了化学反应、辐射和可渗透移动平板的存在等因素。此外,研究还包括热量产生和磁流体力学(MHD)的影响。为了便于分析,最初以偏微分方程表示的控制方程通过相似性转换技术转换成了常微分方程。利用 MATLAB 的 BVP4C 软件的计算能力,有效地求解了这一结果的 ODE 系统。研究成果以图表的形式呈现,生动地描述了各种参数组合下的流场行为、能量守恒和浓度曲线。研究成果以表格的形式进行了周到的总结,提供了不同参数下的温度、速度和质量曲线的全面概述。这些参数包括德博拉数、化学反应速率、埃克特数、路易斯数、普朗特数、孔隙度参数和 MHD 参数。这项研究的一个显著发现是,观察到非维度浓度等值线与化学反应速率大小之间存在反比关系。同时,还观察到麦克斯韦流体的数值越高,温度边界层的厚度就越大。这些发现对涉及复杂流体特性和边界条件的对流中物理和化学现象的复杂相互作用提供了宝贵的见解。温度轮廓随着发热速率的增加而减小,而浓度轮廓则随着化学反应速率的增加而减小。
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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来源期刊
International Journal of Modern Physics B
International Journal of Modern Physics B 物理-物理:凝聚态物理
CiteScore
3.70
自引率
11.80%
发文量
417
审稿时长
3.1 months
期刊介绍: Launched in 1987, the International Journal of Modern Physics B covers the most important aspects and the latest developments in Condensed Matter Physics, Statistical Physics, as well as Atomic, Molecular and Optical Physics. A strong emphasis is placed on topics of current interest, such as cold atoms and molecules, new topological materials and phases, and novel low dimensional materials. One unique feature of this journal is its review section which contains articles with permanent research value besides the state-of-the-art research work in the relevant subject areas.
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