具有速度滑移效应的非牛顿混合纳米流体在汇流和发散通道中的电磁流体力学流动的含义:使用数值方法和 ADM 方法进行的比较研究

Mohamed Kezzar, Abdelaziz Nehal, Pachiyappan Ragupathi, Shekar Saranya, Umair Khan, Mohamed Rafik Sari, Tabet Ismail, Md Irfanul Haque Siddiqui
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摘要

本研究深入探讨了磁场和电场(EMHD)在非牛顿生物混合纳米流体(由银+石墨烯/血液组成)的汇聚和发散几何形状中的流动特性上的复杂相互作用。研究考虑了壁面速度滑移的影响,对这一复杂的流体系统进行了全面考察。研究引入了一种新型生物混合纳米流体模型,其特点是独特地结合了银+石墨烯/血液纳米粒子。为了解决这个多方面的问题,研究采用了基于非线性偏微分方程(PDEs)的数学模型,包括连续性方程和动量方程。然后,通过相似变换将这些偏微分方程转化为非线性常微分方程(ODE)系统。研究探讨了数值解法和分析解法,尤其侧重于阿多米分解法 (ADM) 的应用。为了验证研究结果,研究将分析结果与在特定情况下使用基于 HAM 的 Mathematica 软件包和 Runge-Kutta Fehlberg 4-5 阶 (RKF-45) 方法获得的结果进行了比较。对包括纳米流体体积分数、滑移系数以及磁场和电场影响在内的活性参数进行了系统研究,以揭示它们对这一多元纳米流体系统中的速度和皮肤摩擦力的影响。研究发现,随着纳米粒子体积分数、哈特曼数和两个通道中角度的增加,皮肤摩擦系数也随之减小。研究结果还显示,在收敛段,较高的卡松参数会导致屈服应力增加,但较高的剪切速率会抵消这一影响,从而产生较高的速度曲线。在发散段,由于剪应力降低,流体抵抗流动,导致速度曲线下降。
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Implication of electromagnetohydrodynamic flow of a non‐Newtonian hybrid nanofluid in a converging and diverging channel with velocity slip effects: A comparative investigation using numerical and ADM approaches
This study delves into the intricate interplay of magnetic and electric fields (EMHD) on the flow characteristics of a non‐Newtonian bio‐hybrid nanofluid, consisting of Ag+Graphene/blood, within converging and diverging geometries. The investigation takes into account the effects of velocity slip at the walls, offering a comprehensive examination of this complex fluid system. A novel bio‐hybrid nanofluid model was introduced, featuring a unique combination of Ag+Graphene/blood nanoparticles. To address this multifaceted problem, the research employed mathematical modeling based on nonlinear partial differential equations (PDEs), encompassing continuity and momentum equations. These PDEs were then transformed into a system of nonlinear ordinary differential equations (ODEs) through similarity transformations. The study explored both numerical and analytical solutions, with a particular focus on the application of the Adomian decomposition method (ADM). To validate the findings, the study compared the analytical results with those obtained using the HAM‐based Mathematica package and the Runge–Kutta Fehlberg 4th–5th order (RKF‐45) method in specific scenarios. Active parameters, including nanofluid volume fraction, slip factors, and the influence of magnetic and electric fields, were systematically examined to unveil their impacts on velocity and skin friction within this multifaceted nanofluid system. It is found that the skin friction coefficient decreases with the Increasing both the nanoparticle volume fraction, Hartmann number and the angle in both channels. Results obtained also reveal an in the converging section, higher Casson parameters lead to increased yield stress but are offset by the higher shear rates, resulting in a higher velocity profile. In the diverging section, the fluid resists flow due to the reduced shear stress, leading to a decreased velocity profile.
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