Exact solutions of hydromagnetic convective flow in a microchannel with superhydrophobic slip and temperature jump: Microfluidics applications

IF 2.8 Q2 THERMODYNAMICS
Heat Transfer Pub Date : 2024-04-15 DOI:10.1002/htj.23055
Kiran Sajjan, C. S. K. Raju
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Abstract

The researchers explored the free convective flow of a hybrid nanofluid in a vertical microchannel with a rectangular cross-section. Notably, both channel walls were heated alternately, and a transverse magnetic field was applied across the channel. The channel walls had unique properties, one of which was nonslip and the other was exceedingly hydrophobic. The major purpose was to investigate the effects of magnetism and superhydrophobicity on important flow parameters. The differential equations in the investigation were solved, producing accurate results. The study yielded some significant discoveries. First, when heated, the magnetic parameter reduced skin friction on both sides. Second, in both heating conditions, the magnetic field reduced flow rate and velocity. The flow rates in the two reported situations were similar at a crucial temperature jump coefficient. Furthermore, for low-temperature jump coefficients, heating the superhydrophobic side reduced the Nusselt number whereas heating the nonslip side had no magnetic effect. The percentage change in the value of Nusselt number and velocity decreases continuously with increase in nonlinear density variation with temperature (NDT) parameter and magnetic parameter. The percentage increases in the value of skin friction with increase in temperature jump and slip length but decrease in the percentage of skin friction for the effect of magnetic term and NDT parameter. As the NDT parameter increases, the velocity percentage rises to 50.59% when the superhydrophobic surface is heated and to 84.30% when the nonslip surface is heated. The temperature jump is statistically significant for the value of the Nusselt number and skin friction for the no-slip surface condition. These discoveries have practical consequences for the design and management of both tiny and large-scale systems, with possible applications in microfluidics, microelectronics, nanoscience, and nanotechnology.

具有超疏水滑移和温度跃迁的微通道中水磁性对流的精确解:微流控应用
研究人员探索了混合纳米流体在矩形截面垂直微通道中的自由对流。值得注意的是,两个通道壁交替加热,并在通道上施加横向磁场。通道壁具有独特的性质,其中一个是防滑的,另一个是超疏水的。主要目的是研究磁性和超疏水性对重要流动参数的影响。研究中的微分方程得到了解决,得出了精确的结果。研究得出了一些重要发现。首先,加热时,磁性参数降低了两侧的表皮摩擦。其次,在两种加热条件下,磁场都降低了流速和流量。在关键的温度跃迁系数下,两种报告情况下的流速相似。此外,在低温跃迁系数下,加热超疏水侧会降低努塞尔特数,而加热非防滑侧则没有磁效应。随着非线性密度随温度变化(NDT)参数和磁性参数的增加,努塞尔特数和速度值的百分比变化不断减小。随着温度跃变和滑移长度的增加,表皮摩擦值的百分比增加,但在磁性项和 NDT 参数的影响下,表皮摩擦值的百分比下降。随着无损检测参数的增加,超疏水表面加热时的速度百分比上升到 50.59%,而非滑动表面加热时的速度百分比上升到 84.30%。温度跃迁对于无滑表面条件下的努塞尔特数和皮肤摩擦值具有显著的统计学意义。这些发现对微小和大型系统的设计和管理都有实际意义,可能应用于微流控、微电子学、纳米科学和纳米技术。
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
Heat Transfer
Heat Transfer THERMODYNAMICS-
CiteScore
6.30
自引率
19.40%
发文量
342
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