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Computational Thermal Sciences: An International Journal

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ISSN Imprimer: 1940-2503

ISSN En ligne: 1940-2554

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THERMOPHORESIS AND BROWNIAN MOTION EFFECTS ON MHD MICROPOLAR NANOFLUID FLOW PAST A STRETCHING SURFACE WITH NON-UNIFORM HEAT SOURCE/SINK

Volume 12, Numéro 1, 2020, pp. 55-77
DOI: 10.1615/ComputThermalScien.2020027016
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RÉSUMÉ

This report presents the combined influence of heat and mass transfer on magnetohydrodynamic stagnation point flow of micropolar nanoliquid over a stretching surface. The fluid flow is assumed to be steady and laminar. The impacts of thermal radiation, first order velocity slip, non-uniform heat source/sink, and chemical reaction are considered. The nanofluid model is considered in this work in view of the response of Brownian motion and thermophoresis. Appropriate similarity transformations are used to transform the governing partial differential equations to dimensionless ordinary differential equations (ODEs), which are highly nonlinear and coupled. A fourth order Runge-Kutta-based shooting method is utilized to solve the nonlinear coupled ODEs. Impacts of various physical parameters on the fields of velocity, micro-rotation, and temperature are denoted through graphs. Computations for friction factor, couple stress, local Nusselt number, and Sherwood number are carried out. Results indicate that an increase in the magnitude of Brownian motion and thermophoresis parameters amplifies the thermal field, whereas the fluid concentration becomes reduced with a boost in Brownian motion parameter.

RÉFÉRENCES
  1. Abel, M.S. and Nandeppanavar, M.M., Heat Transfer in MHD Viscoelastic Boundary Layer Flow over a Stretching Sheet with Non-Uniform Heat Source/Sink, Commun. Nonlin. Sci. Numer. Simul., vol. 14, pp. 2120-2131,2009.

  2. Animasaun, I.L., Koriko, O.K., Adegbie, K.S., Babatunde, H.S., Ibraheem, R.O., Sandeep, N., and Mahanthesh, B., Comparative Analysis between 36 nm and 47 nm Alumina-Water Nanofluid Flows in the Presence of Hall Effect, J. Therm. Anal. Calorim., vol. 135, pp. 1-14,2018.

  3. Ashmawy, E.A., Fully Developed Natural Convective Micropolar Fluid Flow in a Vertical Channel with Slip, J. Egypt. Math. Soc., vol. 23, pp. 563-567,2015.

  4. Bachok, N., Ishak, A., and Pop, I., Stagnation Point Flow over a Stretching/Shrinking Sheet in a Nanofluid, Nanoscale Res. Lett., vol. 6, no. 1,pp. 1-10,2011.

  5. Choi, S.U.S. and Eastman, J.A., Enhancing Thermal Conductivity of Fluids with Nanoparticles, ASME-Pub-Fed., vol. 231, pp. 99-106,1995.

  6. Eringen, A.C., Theory of Anisotropic Micropolar Fluids, Int. J. Eng. Sci, vol. 18, no. 1, pp. 5-17,1980.

  7. Hayat, T. and Qasim, M., Influence of Thermal Radiation and Joule Heating on MHD Flow of a Maxwell Fluid in the Presence of Thermophoresis, Int. J. Heat Mass Transf., vol. 53, pp. 4780-4788,2010.

  8. Hayat, T., Ali, S., Awais, M., and Alsaedi, A., Joule Heating Effects in MHD Flow of Burger's Fluid, Heat Transf. Res., vol. 47, no. 12, pp. 1083-1092,2016.

  9. Hiemenz, K., Die Grenzschicht an Einem in den Gleichformingen Flussigkeitsstrom Eingetauchten Garden Kreiszylinder, Dingl Polytech. J, vol. 326, pp. 321-324,1911.

  10. Jang, S.P. and Choi, S.U.S., Role of Brownian Motion in the Enhanced Thermal Conductivity of nanofluids, Appl. Phys. Lett., vol. 84, pp. 4316-4318,2004.

  11. Khan, M.W.A., Waqas, M., Khan, M.I., Alsaedi, A., and Hayat, T., MHD Stagnation Point Flow Accounting Variable Thickness and Slip Effects, ColloidPolym. Sci., vol. 295, pp. 1201-1209,2017.

  12. Khedr, M.E.M., Chamkha, A.J., andBayomi, M., MHD Flow of a Micropolar Fluid past a Stretched Permeable Surface with Heat Generation or Absorption, Nonlin. Anal. Model. Cont., vol. 14, no. 1, pp. 27-40,2017.

  13. Koriko, O.K., Animasaun, I.L., Mahanthesh, B., Saleem, S., Sarojamma, G., and Sivaraj, R., Heat Transfer in the Flow of Blood- Gold Carreau Nanofluid Induced by Partial Slip and Buoyancy, Heat Transf. Asian Res, vol. 47, no. 6, pp. 806-823,2018.

  14. Kumar, K.A., Reddy, J.V.R., Sandeep, N., and Sugunamma, V., Influence of Thermal Radiation on Stagnation Flow towards a Stretching Sheet with Induced Magnetic Field, Adv. Phys. Theo. Appl., vol. 53, pp. 23-28,2016.

  15. Kumar, K.A., Reddy, J.V.R., Sugunamma, V., and Sandeep, N., Impact of Frictional Heating on MHD Radiative Ferrofluid past a Convective Shrinking Surface, Def. Diff. Forum, vol. 378, pp. 157-174,2017.

  16. Kumar, K.A., Reddy, J.V.R., Sugunamma, V., and Sandeep, N., Simultaneous Solutions for MHD Flow of Williamson Fluid over a Curved Sheet with Non-Uniform Heat Source/Sink, Heat Transf. Res., 2018a. DOI: 10.1615/HeatTransRes.2018025939.

  17. Kumar, K.A., Reddy, J.V.R., Sugunamma, V., and Sandeep, N., Magnetohydrodynamic Cattaneo-Christov Flow past a Cone and a Wedge with Variable Heat Source/Sink, Alex. Eng. J, vol. 57, no. 1, pp. 435-443,2018b.

  18. Kumar, K.A., Sugunamma, V., and Sandeep, N., Numerical Exploration of MHD Radiative Micropolar Liquid Flow Driven by Stretching Sheet with Primary Slip: A Comparative Study, J. Non-Equilib. Thermodyn, 2018c. DOI: 10.1515/jnet-2018-0069.

  19. Kumar, K.A., Reddy, J.V.R., Sugunamma, V., and Sandeep, N., Impact of Cross Diffusion on MHD Viscoelastic Fluid Flow past a Melting Surface with Exponential Heat Source, Multi. Mode. Mat. Str., vol. 14, no. 5, pp. 999-1016,2018d.

  20. Kumar, K.A., Sugunamma, V., and Sandeep, N., Impact of Non-Linear Radiation on MHD Non-Aligned Stagnation Point Flow of Micropolar Fluid over a Convective Surface, J. Non-Equilib. Thermodyn, vol. 43, no. 4, pp. 327-345,2018e.

  21. Kumar, K.A., Reddy, J.V.R., Sugunamma, V., and Sandeep, N., MHD Flow of Chemically Reacting Williamson Fluid over a Curved/Flat Surface with Variable Heat Source/Sink, Int. J. Fluid Mech. Res, 2019. DOI: 10.1615/InterJFluid- MechRes.2018025940.

  22. Lakshmi, K.B., Kumar, K.A., Reddy, J.V.R., and Sugunamma, V., Influence of Nonlinear Radiation and Cross Diffusion on MHD Flow of Casson and Walters-B Nanofluids past a Variable Thickness Sheet, J. Nanofluids, vol. 8, pp. 73-83,2019.

  23. Mahanthesh, B., Gireesha, B.J., and Animasaun, I.L., Exploration of Non-Linear Thermal Radiation and Suspended Nanoparticles Effects on Mixed Convection Boundary Layer Flow of Nanoliquids on a Melting Vertical Surface, J. Nanofluids, vol. 7, pp. 833-843,2018.

  24. Makinde, O.D. and Animasaun, I.L., Thermophoresis and Brownian Motion Effects on MHD Bioconvection of Nanofluid with Nonlinear Thermal Radiation and Quartic Chemical Reaction past an Upper Horizontal Surface of a Paraboloid of Revolution, J Mol. Liq., vol. 221, pp. 733-743,2016.

  25. Naveed, M., Abbas, Z., and Sajid, M., MHD Flow of Micropolar Fluid due to a Curved Stretching Sheet with Thermal Radiation, J. Appl. Fluid Mech, vol. 9,no.1,pp. 131-138,2016.

  26. Navier, C.L.M., Sur les lois du Mouvement des Fluides, Mem. Acad. Royal Sci. Inst. Fr., vol. 6, pp. 389-440,1827.

  27. Ramadevi, B., Sugunamma, V., Kumar, K.A., and Reddy, J.V.R., MHD Flow of Carreau Fluid over a Variable Thickness Melting Surface Subject to Cattaneo-Christov Heat Flux, Multi. Model. Mater. Struct., vol. 15, no. 1, 2019.

  28. Reddy, J.V.R., Sugunamma, V., Sandeep, N., and Kumar, K.A., Influence of Non-Uniform Heat Source/Sink on MHD Nanofluid Flow past a Slendering Stretching Sheet with Slip Effects, Global J. Pure Appl. Math., vol. 12, pp. 247-254,2016.

  29. Reddy, J.V.R., Sugunamma, V., and Sandeep, N., Enhanced Heat Transfer in the Flow of Dissipative Non-Newtonian Casson Fluid Flow over a Convectively Heated Upper Surface of a Paraboloid of Revolution, J. Mol. Liq, vol. 229, pp. 380-388,2017.

  30. Reddy, J.V.R., Kumar, K.A., Sugunamma, V., and Sandeep, N., Effect of Cross Diffusion on MHD Non-Newtonian Fluids Flow past a Stretching Sheet with Non-Uniform Heat Source/Sink: A Comparative Study, Alex. Eng. J., vol. 57, no. 3, pp. 1829-1838, 2018.

  31. Sandeep, N. and Sulochana, C., Dual Solutions for Unsteady Mixed Convective Flow of MHD Micropolar Fluid over a Stretch-ing/Shrinking Sheet with Non-Uniform Heat Source/Sink, Eng. Sci. Tech., Int. J., vol. 18, pp. 738-745,2015.

  32. Sandeep, N., Effect of Aligned Magnetic Field on Liquid Thin Film Flow of Magnetic-Nanofluids Embedded with Graphene Nanoparticles, Adv. Powder Tech., vol. 28, no. 3, pp. 865-875,2017.

  33. Sandeep, N. and Animasaun, I.L., Heat Transfer in Wall Jet Flow of Magnetic-Nanofluids with Variable Magnetic Field, Alex. Eng. J., vol. 56, pp. 263-269,2017.

  34. Sandeep, N. and Saleem, S., MHD Flow and Heat Transfer of a Dusty Nanofluid over a Stretching Surface in a Porous Medium, Jordan J. Civil Eng., vol. 11, pp. 149-164,2017.

  35. Sharma, R., Ishak, A., and Pop, I., Partial Slip Flow and Heat Transfer over a Stretching Sheet in a Nanofluid, Math. Prob. Eng., vol. 2013, Article ID: 724547, pp. 1-7, 2013.

  36. Shah, N.A., Animasaun, I.L., Ibtaheem, R.O., Babatunde, H.A., Sandeep, N., and Pop, I., Scrutinization of the Effects of Grashof Number on the Flow of Different Fluids Driven by Convection over Various Surfaces, J. Mol. Liq., vol. 249, pp. 980-990,2018.

  37. Sivaraj, R., Animasaun, I.L., Olabiyi, A., Saleem, S., and Sandeep, N., Gyrotactic Microorganisms and Thermoelectric Effects on the Dynamics of 29 nm CuO-Water Nanofluid over an Upper Horizontal Surface of Paraboloid of Revolution, Multi. Mode. Mat. Str., vol. 14, no. 4, pp. 695-721,2018.

  38. Sulochana, C., Kumar, G.P.A., and Sandeep, N., Effect of Thermophoresis and Brownian Moment on 2D MHD Nanofluid Flow over an Elongated Sheet, Def. Diff. Forum, vol. 377, pp. 111-126,2017a.

  39. Sulochana, C., Samrat, S.P., and Sandeep, N., Boundary Layer Analysis of an Incessant Moving Needle in MHD Radiative Nanofluid with Joule Heating, Int. J. Mech. Sci., vols. 128-129, pp. 326-331,2017b.

  40. Yacob, N.A. and Ishak, A., Micropolar Fluid Flow over a Shrinking Sheet, Meccanica, vol. 47, pp. 293-299,2012.

CITÉ PAR
  1. Irfan M., Rafiq K., Khan M., Waqas M., Anwar M.S., Theoretical analysis of new mass flux theory and Arrhenius activation energy in Carreau nanofluid with magnetic influence, International Communications in Heat and Mass Transfer, 120, 2021. Crossref

  2. Acharya Nilankush, Spectral Simulation to Investigate the Effects of Active Passive Controls of Nanoparticles on the Radiative Nanofluidic Transport Over a Spinning Disk, Journal of Thermal Science and Engineering Applications, 13, 3, 2021. Crossref

  3. Dawar Abdullah, Shah Zahir, Kumam Poom, Alrabaiah Hussam, Khan Waris, Islam Saeed, Shaheen Nusrat, Chemically reactive MHD micropolar nanofluid flow with velocity slips and variable heat source/sink, Scientific Reports, 10, 1, 2020. Crossref

  4. Kumar Ravinder, Kumar Rakesh, Vajravelu K., Sheikholeslami M., Three dimensional stagnation flow of Casson nanofluid through Darcy-Forchheimer space: A reduction to Blasius/Sakiadis flow, Chinese Journal of Physics, 68, 2020. Crossref

  5. Raja Muhammad Asif Zahoor, Khan Zeeshan, Zuhra Samina, Chaudhary Naveed Ishtiaq, Khan Wasim Ullah, He Yigang, Islam Saeed, Shoaib Muhammad, Cattaneo-christov heat flux model of 3D hall current involving biconvection nanofluidic flow with Darcy-Forchheimer law effect: Backpropagation neural networks approach, Case Studies in Thermal Engineering, 26, 2021. Crossref

  6. Alouaoui Reda, Ferhat Samira, Bouaziz M.N., MHD and Stability for Convective Flow of Micropolar Nanofluid over a Moving and Vertical Permeable Plate, Defect and Diffusion Forum, 408, 2021. Crossref

  7. Kumbinarasaiah S., Raghunatha K. R., Rezazadeh Mohammadreza, Inc Mustafa, A solution of coupled nonlinear differential equations arising in a rotating micropolar nanofluid flow system by Hermite wavelet technique, Engineering with Computers, 2021. Crossref

  8. Rehman Saif Ur, Mariam Amna, Ullah Asmat, Asjad Muhammad Imran, Bajuri Mohd Yazid, Pansera Bruno A., Ahmadian Ali, Numerical computation of buoyancy and radiation effects on MHD micropolar nanofluid flow over a stretching/shrinking sheet with heat source, Case Studies in Thermal Engineering, 25, 2021. Crossref

  9. Khan Sohaib, Ali Farhad, Khan Waqar A., Imtiaz Anees, Khan Ilyas, Abdeljawad Thabet, Quasilinearization numerical technique for dual slip MHD Newtonian fluid flow with entropy generation in thermally dissipating flow above a thin needle, Scientific Reports, 11, 1, 2021. Crossref

  10. Patel Harshad R., Cross diffusion and heat generation effects on mixed convection stagnation point MHD Carreau fluid flow in a porous medium, International Journal of Ambient Energy, 2021. Crossref

  11. Alzahrani Faris, Ijaz Khan M., Transportation of binary chemical reaction in entropy optimized micropolar fluid flow with activation energy and internal diffusion effects, Waves in Random and Complex Media, 2021. Crossref

  12. Maisuria M. B., Sonar D. M., Rathod M. K., Nanofluid selection used for coolant in heat exchanger by multiple attribute decision-making method, Journal of Mechanical Science and Technology, 35, 2, 2021. Crossref

  13. Ali Bagh, Khan Shahid Ali, Hussein Ahmed Kadhim, Thumma Thirupathi, Hussain Sajjad, Hybrid nanofluids: Significance of gravity modulation, heat source/ sink, and magnetohydrodynamic on dynamics of micropolar fluid over an inclined surface via finite element simulation, Applied Mathematics and Computation, 419, 2022. Crossref

  14. Ali Bagh, Siddique Imran, Shafiq Anum, Abdal Sohaib, Khan Ilyas, Khan Afrasyab, Magnetohydrodynamic mass and heat transport over a stretching sheet in a rotating nanofluid with binary chemical reaction, non-fourier heat flux, and swimming microorganisms, Case Studies in Thermal Engineering, 28, 2021. Crossref

  15. M D Shamshuddin, Mabood F, A numerical model for analysis of binary chemical reaction and activation energy of thermo solutal micropolar nanofluid flow through permeable stretching sheet: nanoparticle study, Physica Scripta, 96, 7, 2021. Crossref

  16. Han Li-Ping, Shi Hang, Yao Rui-Qi, Wan Wu-Bin, Wen Zi, Lang Xing-You, Jiang Qing, Self-supported Hierarchical Nanoporous Cu/Mo@MoOx Hybrid Electrodes as Robust Nonprecious Electrocatalysts for High-efficiency Hydrogen Evolution, Current Nanoscience, 17, 5, 2021. Crossref

  17. Raza Rabeeah, Naz Rahila, Rabbani Attia, Anjum Asia, Particle and radiative heat transmission in the Sutterby nanoliquid over a curved stretched surface, Waves in Random and Complex Media, 2022. Crossref

  18. Chandel Shikha, Sood Shilpa, Unsteady flow of Williamson fluid under the impact of prescribed surface temperature (PST) and prescribed heat flux (PHF) heating conditions over a stretching surface in a porous enclosure, ZAMM - Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik, 102, 3, 2022. Crossref

  19. Babu Kasibhotla Satya Srinivasa, Parandhama Areti, Vijaya Rachamalla Bhuvana, Significance of heat source/sink on the radiative flow of Cross nanofluid across an exponentially stretching surface towards a stagnation point with chemical reaction, Heat Transfer, 51, 4, 2022. Crossref

  20. Amjad Muhammad, Ahmed Kamran, Akbar Tanvir, Muhammad Taseer, Ahmed Iftikhar, Alshomrani Ali Saleh, Numerical investigation of double diffusion heat flux model in Williamson nanofluid over an exponentially stretching surface with variable thermal conductivity, Case Studies in Thermal Engineering, 36, 2022. Crossref

  21. Shilpa B., Leela V., Prasannakumara B. C., Nagabhushana Pulla, Soret and Dufour effects on MHD double-diffusive mixed convective heat and mass transfer of couple stress fluid in a channel formed by electrically conducting and non-conducting walls, Waves in Random and Complex Media, 2022. Crossref

  22. Madkhali Hadi Ali, Salmi Abdelatif, Alharbi Sayer Obaid, Malik M. Y., Numerical study of enhancement of heat and mass transport in the flow of power-law hybrid nano liquid under chemical reaction, Waves in Random and Complex Media, 2022. Crossref

  23. Obalalu Adebowale Martins, Olayemi Olalekan Adebayo , Odetunde Christopher B. , Ajala Olusegun Adebayo , SIGNIFICANCE OF THERMOPHORESIS AND BROWNIAN MOTION ON A REACTIVE CASSON-WILLIAMSON NANOFLUID PAST A VERTICAL MOVING CYLINDER , Computational Thermal Sciences: An International Journal, 15, 1, 2023. Crossref

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