卡森纳米流体在多孔介质中热泳和布朗运动下通过收缩/拉伸滑片对流对偶解的稳定性分析

IF 0.7 Q2 MATHEMATICS
Kifle Adula Duguma, O. Makinde, L. Enyadene
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引用次数: 2

摘要

本文研究了不可压缩粘性卡森纳米流体在可渗透、对流加热、收缩/拉伸滑片表面上的二维边界层稳定流动。这项工作的成果是非常相关的,无论是理论方面的非牛顿纳米流体流动的数学建模与传热工程系统和工程冷却应用。考虑了吸力/喷射、粘性耗散、对流加热和化学反应的综合影响。利用相似变换将具有边界条件的控制模型偏微分方程转化为非线性常微分方程,最后转化为一阶初值问题。然后,利用四五阶龙格-库塔-费伯格技术与射击法求解数值解。此外,不同的涉及参数对无因次温度、速度和浓度的影响,以及从工程的角度来看,局部努塞尔数、表面摩擦和局部舍伍德数都用图表和表格的形式进行了说明和呈现。对于临界收缩参数λ c,揭示了在λ c < λ < 0区间内存在对偶解,且该范围随吸力参数和滑性参数的增大而增大;因此,两者都控制着流动的稳定性。多孔介质、Casson、Forchheimer、滑度和对流加热参数值的增加减少了局部表面摩擦,提高了质量和传热率。与非牛顿卡森纳米流体相比,牛顿流体(即当卡森参数β趋于无穷∞时)的热边界层厚度、温度分布和表面摩擦减小,而浓度分布、质量和换热率增加。这些结果与已有的结果非常吻合。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Stability Analysis of Dual Solutions of Convective Flow of Casson Nanofluid past a Shrinking/Stretching Slippery Sheet with Thermophoresis and Brownian Motion in Porous Media
This article considered the steady two-dimensional boundary layer flow of incompressible viscous Casson nanofluids over a permeable, convectively heated, shrinking/stretching slippery sheet surface. The achievements of this work are extremely relevant, both theoretically with respect to the mathematical modeling of non-Newtonian nanofluid flow with heat transfer in engineering systems and with respect to engineering cooling applications. The combined impacts of suction/injection, viscous dissipation, convective heating, and chemical reactions were considered. The governing modeled partial differential equations with boundary conditions are transformed into nonlinear ordinary differential equations using similarity transformations and finally converted to the first-order initial value problem. Then, the technique of the fourth-fifth order Runge–Kutta–Fehlberg with the shooting method is used to obtain numerical solutions. Moreover, the effects of different involving parameters on the dimensionless temperature, velocity, and concentration, as well as, from an engineering viewpoint, local Nusselt number, the skin friction, and local Sherwood number are illustrated and presented in graphs and tabular forms. For critical shrinking parameter λ c , the existence of a dual solution within the interval λ c < λ < 0 is revealed, and this range escalates with the suction and slipperiness parameters; hence, both control the flow stability. The increment in the values of the porous media, Casson, Forchheimer, slipperiness, and convective heating parameters reduces the local skin friction and intensifies the rates of mass and heat transfer. For the Newtonian flow (that is, as the Casson parameter β gets to infinity ∞ ), the thermal boundary layer thickness, temperature profile, and skin friction diminish, whereas the concentration profile, mass, and heat transfer rates increase compared to the non-Newtonian Casson nanofluid. These results excellently agree with the existing ones.
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