Mathematical modeling and simulation of magnetized bioconvective nanoliquid flow capturing Brownian motion, multiple slip, thermophoresis and gyrotactic microorganisms configured by rotating disk

Q1 Mathematics Partial Differential Equations in Applied Mathematics Pub Date : 2024-11-13 DOI:10.1016/j.padiff.2024.100989

Hakim AL Garalleh , Sami Ullah Khan , M. Waqas , Nurnadiah Zamri , Barno Abdullaeva , Manish Gupta

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Abstract

This analysis describes the bioconvective flow of nanofluid due to rotation of disk. A uniform suspension of nanofluid between microorganisms is considered to analyze the applications of bioconvection. The nanofluid assumed to be electrically conducting with amplification of magnetic force. The problem is entertained in presence of different slip features including velocity, temperature, concentration and microorganisms. The formulation of problem in simplified form is attained via dimensionless variables. Shooting numerical scheme is used to compute the simulations. Physical interpretation and visualization of results is observed in view of parameters. The observations concluded that interaction of slip effects reduces the velocity profile but enhances nanofluid temperature and concentration profiles. The temperature profile increases with thermophoresis parameter. Current results comprise applications in cooling of electronics devices, thin film coating, gas turbines engine, energy systems etc.

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磁化生物对流纳米液流的数学建模与仿真，捕获布朗运动、多重滑移、热泳和由旋转盘配置的陀螺触觉微生物

该分析描述了纳米流体因圆盘旋转而产生的生物对流。分析生物对流的应用时，考虑了微生物之间均匀悬浮的纳米流体。假定纳米流体导电并具有磁力放大作用。在存在不同滑动特征（包括速度、温度、浓度和微生物）的情况下，对该问题进行了讨论。通过无量纲变量实现了问题的简化表述。使用射击数值方案进行模拟计算。根据参数对结果进行物理解释和可视化观察。观察得出的结论是，滑移效应的相互作用降低了速度曲线，但增强了纳米流体的温度和浓度曲线。温度曲线随着热泳参数的增加而增加。目前的研究成果包括在电子设备冷却、薄膜涂层、燃气涡轮发动机、能源系统等方面的应用。

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