Enhancing the performance of heat radiation and magnetic Nanomaterial's for couple stress trihybrid Nanofluid: Insinuations for biomedical applications

IF 2.5 4区 综合性期刊 Q2 MULTIDISCIPLINARY SCIENCES
Shaaban M. Shaaban , Munawar Abbas , Ainul Akmar Mokhtar , Hilmi Hussin , Mustafa Bayram , Abdullah A. Faqihi , Haitham M. Hadidi , Muhammad Azhar Iqbal
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Abstract

In this paper, the trihybrid hybrid nanofluid bioconvective flow at the stagnation-point with gyrotactic microbes, thermal radiation, and viscous dissipation is considered. Biomedical applications like as medication delivery and the flow dynamics of microcirculatory systems might benefit from the effects of an external and induced MF (magnetic field) produced by Couple Stress THNF (trihybrid Nanofluid) flow over a sheet. In essence, the blood flow is designated by the pair stress fluid model. The purpose is to establish a connection between the recent study and drug delivery applications. This inquiry can provide a clear understanding of the mass and heat transmission behavior of blood flow in a circulatory system as well as numerous hyperthermia treatments, such as the treatment of cancer. The used ternary hybrid nanofluid has blood as the improper liquid along with Cu, Cuo, Fe2O3. The dimensional ODEs are derived from the basic PDEs utilizing the necessary similarity variables. The bvp4c method and a shooting approach are used to show the numerical results of the sped-up equations and boundary conditions. The velocity profile rises with a greater Marangoni convection parameter, whereas the temperature and solutal profiles decrease. Furthermore, the Yamada-Ota ternary hybrid nanofluid model is more important than the Xue model.
增强热辐射和磁性纳米材料在耦合应力三杂交纳米流体中的性能:对生物医学应用的启示
本文研究了三杂化杂化纳米流体在停滞点的生物对流流动,考虑了陀螺效应微生物、热辐射和粘性耗散的影响。生物医学应用,如药物输送和微循环系统的流动动力学,可能受益于由薄片上的耦合应力THNF(三杂交纳米流体)流动产生的外部和诱导MF(磁场)的影响。实质上,血流是由对应力流体模型指定的。目的是建立最近的研究和药物递送应用之间的联系。这项研究可以清楚地了解循环系统中血流的质量和传热行为,以及许多热疗治疗,如癌症的治疗。所使用的三元杂化纳米流体以血液为不适宜液体,同时含有Cu、Cuo、Fe2O3。利用必要的相似性变量,从基本偏微分方程推导出维度偏微分方程。采用bvp4c法和射击法对加速方程和边界条件的数值结果进行了显示。随着Marangoni对流参数的增大,速度剖面增大,而温度和溶质剖面减小。此外,Yamada-Ota三元混合纳米流体模型比Xue模型更重要。
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来源期刊
自引率
5.90%
发文量
130
审稿时长
16 weeks
期刊介绍: Journal of Radiation Research and Applied Sciences provides a high quality medium for the publication of substantial, original and scientific and technological papers on the development and applications of nuclear, radiation and isotopes in biology, medicine, drugs, biochemistry, microbiology, agriculture, entomology, food technology, chemistry, physics, solid states, engineering, environmental and applied sciences.
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