A numerical approach to radiative ternary nanofluid flow on curved geometry with porous media and multiple slip constraints

Muhammad Mumtaz, Saeed Islam, Hakeem Ullah, Abdullah Dawar, Zahir Shah
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Abstract

Energy scarcity is among the biggest global challenges which is aggravating with each passing day due to ever increasing energy demands of contemporary livings as well as industrial requirements verses finite and rapidly depleting fossil reserves of our planet. Improving energy efficiency is one of the effective ways to cope with this challenge. Ternary nanofluids (TNF) are a dynamic novel class of fluids possessing unique thermophysical and other functional characteristics making them the most efficient heat transporting fluids of 21st century. These fluids have promising applications in major manufacturing and processing industries, emerging nanotechnologies and bio‐medical domains. The novel theme of this pragmatic study is analysis of bio‐convective TNF flow by stretchable porous curved surface considering effects of thermal radiation, chemical reaction, magnetic field, and various slip constraints. The modeled partial differential equations (PDEs) governing fluid flow under presumptions are converted to ordinary differential equations (ODEs) by suitable transformation relations. Numerical solutions are presented in graphical sketches and tabular forms using MATLAB bvp4c package for physical interpretations of sundry controlling variables impacts. To gauge veracity of computed results, comparisons with already published results have been presented. Moreover, the statistical concept of Pearson correlation coefficient has been employed to prove strong relationship between slip parameters and physical quantities. Research concludes that thermal efficiency of TNF improves by rising velocity slip, magnetic force, curvature factor, thermal radiation, and thermophoresis effects. Velocity slip and thermal slip improve concentration boundary layer. Gyrotactic microorganisms’ density improves for higher velocity slip, temperature slip while depreciates for larger values of nanoparticle concentration slip and motile organism density slip.
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多孔介质和多滑移约束条件下弯曲几何体上辐射三元纳米流体流动的数值方法
能源短缺是全球面临的最大挑战之一,由于现代生活和工业对能源的需求日益增长,而地球上的化石储量有限且正在迅速枯竭,能源短缺问题日趋严重。提高能源效率是应对这一挑战的有效方法之一。三元纳米流体(TNF)是一类充满活力的新型流体,具有独特的热物理和其他功能特性,是 21 世纪最高效的热传输流体。这些流体在主要制造和加工行业、新兴纳米技术和生物医学领域有着广阔的应用前景。这项务实研究的新主题是分析生物对流 TNF 在可拉伸多孔曲面上的流动,其中考虑到了热辐射、化学反应、磁场和各种滑移约束的影响。通过适当的转换关系,将假定条件下控制流体流动的偏微分方程(PDE)模型转换为常微分方程(ODE)。使用 MATLAB bvp4c 软件包以图形草图和表格的形式给出了数值解,以便对各种控制变量的影响进行物理解释。为了衡量计算结果的真实性,还与已发表的结果进行了比较。此外,还采用了皮尔逊相关系数的统计概念,以证明滑移参数与物理量之间的密切关系。研究得出结论,通过提高速度滑移、磁力、曲率因子、热辐射和热泳效应,TNF 的热效率有所提高。速度滑移和热滑移改善了浓度边界层。速度滑移和温度滑移越大,气动微生物密度越高,而纳米粒子浓度滑移和运动生物密度滑移值越大,气动微生物密度越低。
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