Heat and mass transfer phenomenon for micropolar nanofluid with microrotation effects: Nonsimilarity simulations

Jawad Raza; Kamel Al-Khaled; Sumera Dero; Liaquat Ali Lund; Sami Ullah Khan; M. Ijaz Khan; Attia Boudjemline; Imran Ali Chaudhry; Mohamed Boujelbene; Yassine Bouazzi

doi:10.1142/s0217979223501837

Heat and mass transfer phenomenon for micropolar nanofluid with microrotation effects: Nonsimilarity simulations

Jawad Raza, Kamel Al-Khaled, Sumera Dero, Liaquat Ali Lund, Sami Ullah Khan, M. Ijaz Khan^*, Attia Boudjemline, Imran Ali Chaudhry, Mohamed Boujelbene, Yassine Bouazzi

^*المؤلف المقابل لهذا العمل

نتاج البحث: المساهمة في مجلة › Article › مراجعة النظراء

8 اقتباسات (Scopus)

ملخص

Nonsimilar equations exist in many fluid flow problems and these equations are difficult to be solved using variation of the physical parameters. The key purpose of this study is to find nonsimilarity solution of nanofluid on an exponentially shrunk sheet in the existence of micropolar nanofluid without considerations of the thermal radiation and viscous dissipation effects. The governing partial differential equations (PDEs) are transformed into nonsimilar equations consisting of both ordinary and PDEs. Numerical results of velocity, microrotation, heat and concentration are presented in graphs. The results reveal that fluid particles’ velocity decreases nearby surface and increases afterward. The skin friction, heat and concentration transfer rate are also plotted to perceive the phenomena with different physical situations. It can be deduced that wall shear force f⁰⁰(0) is improved by developed effects of micropolar fluid parameter K and reduced by increasing values of Hartmann number M.

اللغة الأصلية	English
رقم المقال	2350183
دورية	International Journal of Modern Physics B
مستوى الصوت	37
رقم الإصدار	19
المعرِّفات الرقمية للأشياء	https://doi.org/10.1142/s0217979223501837
حالة النشر	Published - يوليو 30 2023
منشور خارجيًا	نعم

ASJC Scopus subject areas

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الوصول إلى المستند

10.1142/s0217979223501837

الملفات والروابط الأخرى

قم بذكر هذا

Raza, J., Al-Khaled, K., Dero, S., Lund, L. A., Khan, S. U., Khan, M. I., Boudjemline, A., Chaudhry, I. A., Boujelbene, M., & Bouazzi, Y. (2023). Heat and mass transfer phenomenon for micropolar nanofluid with microrotation effects: Nonsimilarity simulations. International Journal of Modern Physics B, 37(19), المقال 2350183. https://doi.org/10.1142/s0217979223501837

Heat and mass transfer phenomenon for micropolar nanofluid with microrotation effects: Nonsimilarity simulations. / Raza, Jawad; Al-Khaled, Kamel; Dero, Sumera وآخرون.
في: International Journal of Modern Physics B, المجلد 37, رقم 19, 2350183, ٣٠.٠٧.٢٠٢٣.

نتاج البحث: المساهمة في مجلة › Article › مراجعة النظراء

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abstract = "Nonsimilar equations exist in many fluid flow problems and these equations are difficult to be solved using variation of the physical parameters. The key purpose of this study is to find nonsimilarity solution of nanofluid on an exponentially shrunk sheet in the existence of micropolar nanofluid without considerations of the thermal radiation and viscous dissipation effects. The governing partial differential equations (PDEs) are transformed into nonsimilar equations consisting of both ordinary and PDEs. Numerical results of velocity, microrotation, heat and concentration are presented in graphs. The results reveal that fluid particles{\textquoteright} velocity decreases nearby surface and increases afterward. The skin friction, heat and concentration transfer rate are also plotted to perceive the phenomena with different physical situations. It can be deduced that wall shear force f00(0) is improved by developed effects of micropolar fluid parameter K and reduced by increasing values of Hartmann number M.",

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AU - Dero, Sumera

AU - Lund, Liaquat Ali

AU - Khan, Sami Ullah

AU - Khan, M. Ijaz

AU - Boudjemline, Attia

AU - Chaudhry, Imran Ali

AU - Boujelbene, Mohamed

AU - Bouazzi, Yassine

N1 - Publisher Copyright: © World Scientific Publishing Company.

PY - 2023/7/30

Y1 - 2023/7/30

N2 - Nonsimilar equations exist in many fluid flow problems and these equations are difficult to be solved using variation of the physical parameters. The key purpose of this study is to find nonsimilarity solution of nanofluid on an exponentially shrunk sheet in the existence of micropolar nanofluid without considerations of the thermal radiation and viscous dissipation effects. The governing partial differential equations (PDEs) are transformed into nonsimilar equations consisting of both ordinary and PDEs. Numerical results of velocity, microrotation, heat and concentration are presented in graphs. The results reveal that fluid particles’ velocity decreases nearby surface and increases afterward. The skin friction, heat and concentration transfer rate are also plotted to perceive the phenomena with different physical situations. It can be deduced that wall shear force f00(0) is improved by developed effects of micropolar fluid parameter K and reduced by increasing values of Hartmann number M.

AB - Nonsimilar equations exist in many fluid flow problems and these equations are difficult to be solved using variation of the physical parameters. The key purpose of this study is to find nonsimilarity solution of nanofluid on an exponentially shrunk sheet in the existence of micropolar nanofluid without considerations of the thermal radiation and viscous dissipation effects. The governing partial differential equations (PDEs) are transformed into nonsimilar equations consisting of both ordinary and PDEs. Numerical results of velocity, microrotation, heat and concentration are presented in graphs. The results reveal that fluid particles’ velocity decreases nearby surface and increases afterward. The skin friction, heat and concentration transfer rate are also plotted to perceive the phenomena with different physical situations. It can be deduced that wall shear force f00(0) is improved by developed effects of micropolar fluid parameter K and reduced by increasing values of Hartmann number M.

KW - Micropolar nanofluid

KW - microrotation effects

KW - nonsimilarity equations

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KW - stability analysis

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