Peristalsis of carbon nanotubes with radiative heat flux

被引:0
作者
S. Farooq
M. I. Khan
M. Waqas
T. Hayat
A. Alsaedi
机构
[1] PMAS Arid Agriculture University Shamsabad,Deparment of Mathematics and Statistics
[2] Quaid-I-Azam University,Department of Mathematics
[3] National University of Technology,NUTECH School of Applied Sciences and Humanities
[4] King Abdulaziz University,Nonlinear Analysis and Applied Mathematics (NAAM) Research Group, Department of Mathematics, Faculty of Science
来源
Applied Nanoscience | 2020年 / 10卷
关键词
Peristaltic flow; Viscosity (temperature dependent); Radiative heat flux; Effective heat transfer rate (i.e. Nusselt number); Trapped bolus;
D O I
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中图分类号
学科分类号
摘要
The purpose of this analysis is to highlight the CNTs characteristics in peristaltic flows through non-uniform channels. Viscosity is considered temperature in this analysis. Peristaltic walls comprise the momentum and thermal slip effects. Radiative heat flux is also taken into account to study the thermal radiation aspects. Physical properties for CNTS (i.e. single and multiple wall) are used which was suggested by Iijima. Flow equations are modeled in view of mass, momentum and energy conservation principles. Moreover, such equations are simplified through lubrication assumptions. Solution for flow quantities is carried out in the form of exact solution. Numerical integration technique is used for pressure rise per wavelength plotting. Bar charts are made for effective heat transfer rate analysis.
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页码:347 / 357
页数:10
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共 82 条
[1]  
Abd-Alla AM(2013)Effect of rotation on peristaltic flow of a micropolar fluid through a porous medium with an external magnetic field J Mag Mag Mater 348 33-43
[2]  
Abo-Dahab SM(2018)Fallopian tube analysis of the peristaltic-ciliary flow of third grade fluid in a finite narrow tube Chin J Phy 56 605-621
[3]  
Al-Simery RD(2016)Simultaneous effects of slip and MHD on peristaltic blood flow of Jeffrey fluid model through a porous medium Alexandria Eng J 55 1017-1023
[4]  
Ashraf H(1952)The viscosity of concentrated suspensions and solutions J Chem Phys 20 571-581
[5]  
Siddiqui AM(1995)Enhancing thermal conductivity of fluid with nanoparticles Dev Appl Non-Newton Flows ASME N Y 66 99-105
[6]  
Rana MA(2013)The effects of MHD and temperature dependent viscosity on the flow of non-Newtonian nanofluid in a pipe: analytical solutions Appl Math Modell 37 1451-1457
[7]  
Bhatti MM(2017)Numerically framing the features of second order velocity slip in mixed convective flow of Sisko nanomaterial considering gyrotactic microorganisms Int J Heat Mass Transf 112 521-532
[8]  
Abbas MA(2018)MHD flow of Eyring-Powell liquid in convectively curved configuration J Braz Soc Mech Sci Eng 40 159-1143
[9]  
Brinkman HC(2016)Influence of variable viscosity and radial magnetic field on peristalsis of copper-water nanomaterial in a non-uniform porous medium Int J Heat Mass Transf 103 1133-710
[10]  
Choi SUS(2016)Impact of Cattaneo–Christov heat flux model in flow of variable thermal conductivity fluid over a variable thicked surface Int J Heat Mass Transf 99 702-55
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