实施布昂尼奥尔诺模型的高阶化学反应对生物流动碳纳米管的影响

IF 1.2 4区 综合性期刊 Q3 MULTIDISCIPLINARY SCIENCES
Azad Hussain , Saira Raiz , Ali Hassan , S.H. Elhag , Mohammad Mahtab Alam , Ahmed M. Hassan , Hedia Zardi
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引用次数: 0

摘要

近年来,基于碳纳米管在电极、超级电容器、纳米线、传感器、聚合物涂层、生物医学和机械应用等领域的大量应用,人们对碳纳米管进行了广泛的探索。考虑到碳纳米管在微电化学系统传热过程中的重要作用,本研究旨在考察碳纳米管在使用混合物基础工作流体时的传热属性。这项研究的重点是阐述高级化学反应对碳纳米管生物对流的影响。此外,还使用了改进的 Buongiorno 纳米流体模型,该模型考虑了热泳和布朗运动效应。加热边界条件也与运动微生物的迁移结合在一起。这项工作遵循了混合纳米流体机制。单层和多层碳纳米管与乙二醇(EG)和乙二醇/水(EG-水)等不同工作流体同时使用。使用 bvp-4c 软件包处理了非三维流动模型方程。所获得的结果显示了不同的剖面,并以表格形式列出了表面摩擦系数和传热系数的数据集。据观察,当布朗运动水平增加时,与 SWCNT-MWCNT/EG 水混合纳米流体相比,SWCNT-MWCNT/EG 纳米流体的速度曲线会突然下降。随着磁化值的增加,出现了相反的行为。高普朗特数会降低两种混合纳米流体的热边界层厚度。随着生物对流路易斯数的增加,运动微生物的轮廓也随之扩大。此外,还对阻力和努塞尔特数的结果进行了比较,结果发现两者非常吻合。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Consequences of higher order chemical reaction on bioconvective carbon nanotubes flow implementing Buongiorno's model

In recent years, carbon nanotubes have been extensively explored based on numerous applications in fields such as carbon nanotube based electrodes, super capacitors, nanowires, sensors, coating with polymers, biomedical, and mechanical applications. Keeping in view the significance of carbon nanotubes in the heat transfer process in micro-electrochemical systems, this study is conducted to examine the heat transfer attributes of the carbon nanotubes using the mixture base working fluid. The focus of this investigation is to elaborate the consequence of higher chemical reactions on the bioconvective flow of carbon nanotubes. Additionally, modified Buongiorno's nanofluid model has been used, which undertakes thermophoresis and Brownian motion effects. Heated boundary condition has also been incorporated with the migration of motile microorganisms. The hybrid nanofluid mechanism has been followed in this work. Carbon nanotubes of single-layer and multi-layer have been used simultaneously with different working fluids, such as ethylene glycol (EG) and ethylene glycol/water (EG-water). Non-dimensional flow model equations have been tackled with the bvp-4c package. The obtained outcomes have been presented for distinct profiles and tabulated data sets for the surface skin friction and heat transfer coefficient. It has been observed that when the level of Brownian motion increases, the velocity profile decreases abruptly for SWCNT-MWCNT/EG as compared to SWCNT-MWCNT/EG-water hybrid nanofluid. Opposite behavior has been seen with raising values of magnetization. High Prandtl number decrease thermal boundary layer thickness for both types of hybrid nanofluids. The motile microorganism profile expands by raising the level of bioconvective Lewis number. Moreover, the outcomes of drag force and Nusselt number have been compared, and good agreement has been found.

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来源期刊
Kuwait Journal of Science
Kuwait Journal of Science MULTIDISCIPLINARY SCIENCES-
CiteScore
1.60
自引率
28.60%
发文量
132
期刊介绍: Kuwait Journal of Science (KJS) is indexed and abstracted by major publishing houses such as Chemical Abstract, Science Citation Index, Current contents, Mathematics Abstract, Micribiological Abstracts etc. KJS publishes peer-review articles in various fields of Science including Mathematics, Computer Science, Physics, Statistics, Biology, Chemistry and Earth & Environmental Sciences. In addition, it also aims to bring the results of scientific research carried out under a variety of intellectual traditions and organizations to the attention of specialized scholarly readership. As such, the publisher expects the submission of original manuscripts which contain analysis and solutions about important theoretical, empirical and normative issues.
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