Microconvection of MHD Solarized Nanofluid in the Presence of Double Slip and Surface Suction

Naseer Muhammad Khan, K. M. Abualnaja
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Abstract

In recent years, some researchers have analyzed nanofluids and tried to identify potential active ingredients that give nanofluids enormous thermal conductivity (nanoparticle suspensions). In such suspensions, the Brownian motion of the nanoparticles is the only technique expected to enhance the thermal conductivity of the nanofluids, and the sections that can contribute to this are the subject of rules and discussion. When studying the flow, the influence of Brownian motion through the implantation of nanoparticles into the base fluid was investigated and came to the conclusion that Brownian motion of nanoparticles is the only means associated with the enormously improved thermal conductivity of nanofluids. Suction is the only viable way to control cooling rate in multiple product formation processes. The quality and mechanical properties of the final product can be improved by controlling the cooling rate during the melting of raw material and the subsequent condensation process. Slip conditions of the first and second order are also included in the current development. An interesting feature of this model is that the Brownian motion of nanoparticles can be accelerated by solar energy, thereby increasing the temperature of the base fluid. These interesting features increase the demand for this model in many industrial applications.
双滑移和表面吸力作用下MHD固化纳米流体的微对流
近年来,一些研究人员对纳米流体进行了分析,并试图找出使纳米流体具有巨大导热性的潜在活性成分(纳米颗粒悬浮液)。在这样的悬浮液中,纳米颗粒的布朗运动是唯一有望提高纳米流体导热性的技术,而能够有助于这一点的部分是规则和讨论的主题。在研究流体流动时,研究了纳米颗粒注入基液时布朗运动的影响,并得出结论:纳米颗粒的布朗运动是极大提高纳米流体导热性的唯一手段。在多种产品形成过程中,抽吸是控制冷却速度的唯一可行方法。通过控制原料熔化和随后的冷凝过程中的冷却速度,可以提高最终产品的质量和机械性能。目前的开发还包括了一阶和二阶滑移条件。这个模型的一个有趣的特点是,纳米粒子的布朗运动可以被太阳能加速,从而提高基流体的温度。这些有趣的特性增加了许多工业应用对该模型的需求。
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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