Significance of variable thermal conductivity and suction/injection in unsteady MHD mixed convection flow of Casson Williamson nanofluid through heat and mass transport with gyrotactic microorganisms

Abdelmooty Mohamed Abd‐Alla, Esraa N. Thabet, Hany A. Hosham, S. M. M. El‐Kabeir
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Abstract

The present paper explores a two‐dimensional mixed bio‐convective unsteady viscous hydro‐magnetic Casson Williamson nanofluid flow model with heat and mass transport incorporating motile microorganisms towards a stretchy spinning disc. The flow concept is accomplished by rotating a stretched disc with a time‐varying angular velocity. By applying a magnetic field normal to the axial direction, a magnetic interaction is taken into consideration. The Casson Williamson nanofluid contains nanosized particles suspended with swimming motile microorganisms and the rotation of the disc is exhibited by buoyancy forces, thermophoresis, suction/injection, zero mass flux conditions, variable thermal conductivity, Joule heating and so forth. The obtained flow narrating differential equations of the model are transformed into ordinary differential system. This is accomplished by simulating boundary value problems using the shooting technique using the ‘ND‐Solve’ approach included in the Mathematica software (Mathematica 12). The implications of the engaged parameters such as Williamson fluid parameter, Casson fluid (CF) parameter, thermophoresis parameter, Brownian motion parameter and so forth, on both axial and radial velocities, temperature, concentration of nanoparticles and microorganisms are explained by means of graphical and tabular constructions. This paper's validity has been confirmed and its findings align with those of other previously published papers. Furthermore, it is found that both the axial and radial velocity profiles are seen to be diminishing functions of the CF parameter. The identified observation may have theoretical implications for a number of engineering procedures, solar energy systems, biofuel cells and extrusion system improvement. Moreover, this work finds application in micro‐fabrication techniques and the chemical industry.
在卡森-威廉姆森纳米流体的非稳态 MHD 混合对流中,可变导热系数和抽吸/注入对陀螺仪微生物热量和质量传输的影响
本文探讨了一种二维混合生物对流非稳态粘性水磁卡逊-威廉姆森纳米流体模型,该模型具有热量和质量传输功能,将运动微生物融入到一个拉伸旋转圆盘中。流动概念是通过以随时间变化的角速度旋转拉伸圆盘来实现的。通过在轴向施加法向磁场,考虑了磁场相互作用。卡森-威廉姆森纳米流体包含悬浮着游动微生物的纳米颗粒,圆盘的旋转受到浮力、热泳、吸力/喷射、零质量通量条件、可变热导率、焦耳热等因素的影响。得到的模型流动微分方程被转换成常微分系统。这是通过使用 Mathematica 软件(Mathematica 12)中的 "ND-Solve "方法,使用射击技术模拟边界值问题来实现的。本文通过图表说明了威廉姆森流体参数、卡森流体(CF)参数、热泳参数、布朗运动参数等参与参数对轴向和径向速度、温度、纳米颗粒和微生物浓度的影响。本文的有效性已得到证实,其研究结果与之前发表的其他论文一致。此外,本文还发现轴向和径向速度曲线都是 CF 参数的递减函数。这一发现可能对许多工程程序、太阳能系统、生物燃料电池和挤压系统的改进具有理论意义。此外,这项工作还可应用于微细加工技术和化学工业。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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