Melting heat transfer properties on the magnetohydrodynamic flow of CNT-water nanofluids over an expanding surface

Q1 Mathematics

Partial Differential Equations in Applied Mathematics Pub Date : 2025-04-24 DOI:10.1016/j.padiff.2025.101212

Nilanchala Sethy, S.R. Mishra

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Abstract

The significance of velocity slip in relation to the melting condition is examined in the current analysis for the flow of nanofluid via a stretching cylinder. However, magnetisation's importance for including transverse magnetic field is vital. As a novel study the use of “Single-Wall Carbon Nanotube” (SWCNT) and “Multi-Wall Carbon Nanotube” (MWCNT) nanocomposites are immersed in base liquid water for the thermal enhancement properties. As a result, the current model is designed to study the interaction of radiating energy and has various uses in the aforementioned fields. However, the prosed model is solved numerically deploying the traditional “Runge-Kutta-fourth-order” technique accomplished with shooting. Graphics are used to illustrate the properties of different physical elements connected to the governing equations. The analysis pertaining to the parameters is pronounced briefly. The main outputs are: The thickness of the thermal bounding surface increases due to the combined effect of volume concentration and thermal radiation, whereas the thickness decreases as a result of the heat supplier enhancing the profile.

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碳纳米管-水纳米流体在膨胀表面上磁流体动力学流动的熔融传热特性

在当前的纳米流体通过拉伸圆柱体流动分析中，研究了速度滑移与熔化条件的关系。然而，磁化对于包括横向磁场的重要性是至关重要的。将“单壁碳纳米管”（SWCNT）和“多壁碳纳米管”（MWCNT）纳米复合材料浸泡在基材液态水中进行热增强性能的研究是一项新的研究。因此，目前的模型是为了研究辐射能的相互作用而设计的，在上述领域有多种用途。然而，所提出的模型是采用传统的“龙格-库塔-四阶”技术通过射击完成的数值求解。图形用来说明与控制方程相关的不同物理元素的性质。简要地说明有关参数的分析。主要输出是：由于体积浓度和热辐射的共同作用，热边界面的厚度增加，而由于热源对剖面的强化，热边界面的厚度减小。

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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