The varying viscosity impact in an inclined peristaltic channel with diffusion‐thermo and thermo‐diffusion

Anum Tanveer, Sharak Jarral, A. Al‐Zubaidi, Salman Saleem, Neyara Radwan
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Abstract

A mathematical model is constructed to investigate the behavior of peristaltic flow of Jeffrey fluid in an inclined tapered asymmetric porous channel. The fluid viscosity is taken as space dependent variable quantity. Heat absorption, Soret and Dufour effects are also retained in the current scrutiny. These preferences have broad applications in engineering, biology and industry. We began our investigation by taking into account the two‐dimensional inclined asymmetric porous channel. In the context of mathematical modeling, the appropriate dimensional nonlinear equations for momentum, heat and mass transport are simplified into dimensionless equations by applying the essential estimation of long wavelength and low Reynolds number. The solution of the governing equations is executed numerically. A graphical depiction of many crucial physical characteristics on velocity, temperature, concentration, heat transfer rate, Nusselt number and Streamlines have been reported in ending section. Temperature profile exhibits an escalation with the augmentation of Brinkman number and Dufour number . For the growing values of Prandtl number , an increment in temperature profile is observed whilst a reverse tendency is captured for concentration profile. It is noted that concentration profile falls down owing to the enhancement in Soret number and Schmidt number . An oscillatory outlook is noticed for heat transfer rate and Nusselt number. The novelty of this proposed model in the research domain specifically depends on considerations of the combined study of the Variable viscosity, Darcy resistance, Viscous dissipation, Mixed convention, Heat absorption, Soret and Dufour effects in peristaltic flow of non‐ Newtonian Jeffrey fluid in an inclined Asymmetric tapered channel under the influence of convective boundary conditions.
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倾斜蠕动通道中粘度变化对扩散-热力学和热扩散的影响
本文构建了一个数学模型,用于研究杰弗里流体在倾斜锥形非对称多孔通道中的蠕动流动行为。流体粘度是空间变量。吸热、Soret 和 Dufour 效应也保留在当前的研究中。这些偏好在工程、生物和工业领域有着广泛的应用。我们从二维倾斜不对称多孔通道开始研究。在数学建模方面,通过对长波长和低雷诺数的基本估计,将动量、热量和质量传输的适当维度非线性方程简化为无维度方程。治理方程的求解采用数值方法。结尾部分报告了速度、温度、浓度、传热率、努塞尔特数和流线等许多关键物理特性的图形描述。温度曲线随着布林克曼数和杜富尔数的增加而上升。当普朗特数的值不断增大时,温度曲线也随之上升,而浓度曲线则呈现相反的趋势。我们注意到,由于索雷特数和施密特数的增大,浓度曲线下降。热传导率和努塞尔特数呈现振荡趋势。该模型在研究领域的新颖性主要取决于在对流边界条件的影响下,对非牛顿杰弗里流体在倾斜的非对称锥形通道中蠕动流动时的可变粘度、达西阻力、粘性耗散、混合惯例、吸热、索雷特和杜福尔效应的综合研究。
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