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广义磁电 Oldroyd-B 生物纳米流体在倾斜条件下可渗透介质中的传热传质的比较研究。

Comparative study of heat and mass transfer of generalized MHD Oldroyd-B bio-nano fluid in a permeable medium with ramped conditions.

机构信息

Nanchang Institute of Technology, Nanchang, 30044, China.

School of Mathematics and Statistics, Xuzhou University of Technology, Xuzhou, 221018, China.

出版信息

Sci Rep. 2021 Dec 6;11(1):23454. doi: 10.1038/s41598-021-02326-8.

DOI:10.1038/s41598-021-02326-8
PMID:34873194
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8648785/
Abstract

This article aims to investigate the heat and mass transfer of MHD Oldroyd-B fluid with ramped conditions. The Oldroyd-B fluid is taken as a base fluid (Blood) with a suspension of gold nano-particles, to make the solution of non-Newtonian bio-magnetic nanofluid. The surface medium is taken porous. The well-known equation of Oldroyd-B nano-fluid of integer order derivative has been generalized to a non-integer order derivative. Three different types of definitions of fractional differential operators, like Caputo, Caputo-Fabrizio, Atangana-Baleanu (will be called later as [Formula: see text]) are used to develop the resulting fractional nano-fluid model. The solution for temperature, concentration, and velocity profiles is obtained via Laplace transform and for inverse two different numerical algorithms like Zakian's, Stehfest's are utilized. The solutions are also shown in tabular form. To see the physical meaning of various parameters like thermal Grashof number, Radiation factor, mass Grashof number, Schmidt number, Prandtl number etc. are explained graphically and theoretically. The velocity and temperature of nanofluid decrease with increasing the value of gold nanoparticles, while increase with increasing the value of both thermal Grashof number and mass Grashof number. The Prandtl number shows opposite behavior for both temperature and velocity field. It will decelerate both the profile. Also, a comparative analysis is also presented between ours and the existing findings.

摘要

本文旨在研究 ramped 条件下的磁电流体 Oldroyd-B 热质传递。Oldroyd-B 流体被视为基液(血液),其中悬浮有金纳米粒子,以形成非牛顿生物磁纳米流体溶液。表面介质采用多孔介质。众所周知的整阶导数 Oldroyd-B 纳米流体方程已被推广到非整阶导数。使用了三种不同类型的分数阶微分算子定义,如 Caputo、Caputo-Fabrizio、Atangana-Baleanu(稍后将称为 [Formula: see text]),以建立所得的分数阶纳米流体模型。通过拉普拉斯变换获得温度、浓度和速度分布的解,并且使用两种不同的逆数值算法,如 Zakian 的和 Stehfest 的,来求解。这些解也以表格形式呈现。为了了解各种参数(如热格拉肖夫数、辐射因子、质量格拉肖夫数、施密特数、普朗特数等)的物理意义,我们以图形和理论的方式进行了解释。纳米流体的速度和温度随着金纳米粒子的增加而降低,而随着热格拉肖夫数和质量格拉肖夫数的增加而增加。普朗特数对温度和速度场表现出相反的行为。它会使两个分布都减速。此外,我们还对本文结果与现有结果进行了比较分析。

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