麦克斯韦纳米流体在多孔拉伸状态下的辐射不稳定流的罗宾和零质量扩散分析:分析模拟

Manzoor Ahmad, Sami Ullah Khan, Qudsia Bibi, Muhammad Taj, Iskander Tlili, Faisal Mehmood Butt
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引用次数: 0

摘要

由于纳米材料的多学科应用,最近对这一主题进行了广泛的研究。当前研究的目的是分析与零质量热约束相关的麦克斯韦纳米流体的非稳态流动对传热的促进作用。辐射现象和磁力的应用有助于解决当前的流动问题。分析受制于罗宾和零质量扩散约束的实施。一个双向移动的多孔表面认可了流动。采用适当的变量来简化系统。同调分析法(HAM)用于计算求解过程。所得结果与已进行的研究结果相吻合。据观察,当非稳态参数值越高时,温度和纳米粒子浓度分布越小。
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Robin and zero‐mass diffusion analysis for radiated unsteady flow of Maxwell nanofluid due to porous stretched regime: Analytical simulations
Owing to the multidisciplinary applications of nanomaterials, a wide range of research has been conducted on this topic recently. The aim of current research is to analyze the enhancement of heat transfer due to the unsteady flow of Maxwell nanofluid associated with the zero mass thermal constraints. The applications of the radiated phenomenon and magnetic force are contributed to the current flow problem. The analysis is subject to the implementation of Robin and zero‐mass diffusion constraints. A bidirectional moving porous surface endorsed the flow. The appropriate variables are taken for simplifying the system. The homotopy analysis method (HAM) is used to compute the solution procedure. The obtained results are confirmed with already performed studies. It has been observed that the temperature and nanoparticle concentration distributions decrease for higher unsteady parameter values.
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