Enhanced energy efficiency by implementing MHD flow and heat transfer in Cu-Al2O3/H2O hybrid nanoparticles with variable viscosity

IF 5.45 Q1 Physics and Astronomy

Nano-Structures & Nano-Objects Pub Date : 2024-11-23 DOI:10.1016/j.nanoso.2024.101412

Aaqib Majeed , Parvez Ali , Marouan Kouki , Muhammad Kashif Siddhu

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引用次数: 0

Abstract

Hybrid nanofluids are engaged in phase-change materials and thermal energy storage systems to enhance heat transfer during the charging and discharging processes. Improved understanding of how variable viscosity and thermal radiation affect these fluids contributes to more efficient energy management. This study aims to formulate an efficient mathematical model for the two-dimensional flow of a hybrid nanofluid composed of copper

(Cu)

and alumina oxide

(A l_{2} O_{3})

suspended with base fluid

H_{2} O

to form a hybrid fluid under the influence of thermal radiation. The present study also integrates the effects of variable viscosity and viscous dissipation. Electromagnetic radiation impact due to temperature also amalgamated. The governing PDEs are reformulated into ODEs via tailored similarity transformations. These reformulated equations are then numerically resolved using Bvp4c solver, leveraging the shooting method within MATLAB for precision and efficiency. The most significant results are predetermined relevant parameters, such as the prosperity parameter, magnetic parameter, radiation parameter, slip velocity parameter

,

Biot number, convention parameter, Eckert number, heat source parameter, Prandtl number on velocity and temperature distribution are inspected graphically and in the form of table. Outcomes illustrate that fluid velocity flattens by increasing magnetic parameters because there exists a Lorentz force that opposes the fluid motion, whereas enhancement is noted via radiation parameter. Compared to conventional nanofluid, temperature curves of hybrid nanoliquid is higher. Furthermore, recent results indicate strong agreement for a specific instance.

查看原文本刊更多论文

通过在粘度可变的 Cu-Al2O3/H2O 混合纳米粒子中实施 MHD 流动和传热提高能源效率

混合纳米流体用于相变材料和热能储存系统，以增强充放电过程中的热传递。提高对可变粘度和热辐射如何影响这些流体的认识有助于实现更高效的能源管理。本研究旨在为由铜（Cu）和氧化铝（Al2O3）组成的混合纳米流体在热辐射影响下的二维流动建立一个有效的数学模型。本研究还综合考虑了可变粘度和粘性耗散的影响。此外，还综合了温度引起的电磁辐射影响。通过量身定做的相似性变换，理事 PDEs 被重新表述为 ODEs。然后，使用 Bvp4c 求解器对这些重构方程进行数值求解，并利用 MATLAB 中的射击法提高精度和效率。最重要的结果是预先确定的相关参数，如繁荣参数、磁参数、辐射参数、滑移速度参数、Biot 数、约定参数、Eckert 数、热源参数、Prandtl 数对速度和温度分布的影响，并以图形和表格的形式进行了检验。结果表明，由于存在反对流体运动的洛伦兹力，流体速度会随着磁参数的增加而变平，而辐射参数则会增强流体速度。与传统纳米流体相比，混合纳米液体的温度曲线更高。此外，最近的研究结果表明，在一个特定的实例中，二者具有很强的一致性。

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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来源期刊

Nano-Structures & Nano-Objects Physics and Astronomy-Condensed Matter Physics

CiteScore

9.20

自引率

0.00%

发文量

审稿时长

22 days

期刊介绍： Nano-Structures & Nano-Objects is a new journal devoted to all aspects of the synthesis and the properties of this new flourishing domain. The journal is devoted to novel architectures at the nano-level with an emphasis on new synthesis and characterization methods. The journal is focused on the objects rather than on their applications. However, the research for new applications of original nano-structures & nano-objects in various fields such as nano-electronics, energy conversion, catalysis, drug delivery and nano-medicine is also welcome. The scope of Nano-Structures & Nano-Objects involves: -Metal and alloy nanoparticles with complex nanostructures such as shape control, core-shell and dumbells -Oxide nanoparticles and nanostructures, with complex oxide/metal, oxide/surface and oxide /organic interfaces -Inorganic semi-conducting nanoparticles (quantum dots) with an emphasis on new phases, structures, shapes and complexity -Nanostructures involving molecular inorganic species such as nanoparticles of coordination compounds, molecular magnets, spin transition nanoparticles etc. or organic nano-objects, in particular for molecular electronics -Nanostructured materials such as nano-MOFs and nano-zeolites -Hetero-junctions between molecules and nano-objects, between different nano-objects & nanostructures or between nano-objects & nanostructures and surfaces -Methods of characterization specific of the nano size or adapted for the nano size such as X-ray and neutron scattering, light scattering, NMR, Raman, Plasmonics, near field microscopies, various TEM and SEM techniques, magnetic studies, etc .