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International Journal of Modelling and Simulation Volume 43, 2023 - Issue 4
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Articles

MHD Casson Nanofluid in Darcy-Forchheimer Porous Medium in the Presence of Heat Source and Arrhenious Activation Energy: Applications of Neural Networks

Muhammad Shoaiba Department of Mathematics, COMSATS University Islamabad, Attock Campus, Attock, PakistanView further author information
,
Shafaq Nazb Department of Mathematics, University of Gujrat, Gujrat, PakistanView further author information
,
Kottakkaran Sooppy Nisarc Department of Mathematics, College of Arts and Science, Prince Sattam bin Abdulaziz University, Saudi ArabiaCorrespondence[email protected] [email protected]
View further author information
,
Muhammad Asif Zahoor Rajad Future Technology Research Center, National Yunlin University of Science and Technology, Douliou, TaiwanCorrespondence[email protected]
View further author information
,
Sana Aslamb Department of Mathematics, University of Gujrat, Gujrat, PakistanView further author information
&
Iftikhar Ahmadb Department of Mathematics, University of Gujrat, Gujrat, PakistanView further author information
Pages 438-461 | Received 04 Apr 2022, Accepted 16 Jun 2022, Published online: 24 Jun 2022

References

  • Arrhenius S. Quantitative relationship between the rate a reaction proceeds and its temperature. J Phys Chem. 1889;4:226–248.
  • Bestman AR. Radiative heat transfer to flow of a combustible mixture in a vertical pipe. Int J Energy Res. 1991;15(3):179–184.
  • Mullin AS, Guo H, McCoy AB. New physical insights from kinetics studies. The Journal of Physical Chemistry A. 2019;123(14): 3057.
  • Shoaib M, Raja MAZ, Farhat I, et al. Soft computing paradigm for Ferrofluid by exponentially stretched surface in the presence of magnetic dipole and heat transfer. Alexandria Eng J. 2021;61(2): 1607–1623.
  • Arain MB, Bhatti MM, Zeeshan A, et al. Analysis of Arrhenius kinetics on multiphase flow between a pair of rotating circular plates. Math Prob Eng. 2020;2020. DOI:10.1155/2020/2749105
  • Shoaib M, Zubair G, Nisar KS, et al. Ohmic heating effects and entropy generation for nanofluidic system of Ree-Eyring fluid: intelligent computing paradigm. Int J Heat Mass Transf. 2021;129:105683.
  • Jensen TL, Moxnes JF, Unneberg E, et al. Models for predicting impact sensitivity of energetic materials based on the trigger linkage hypothesis and Arrhenius kinetics. J Mol Model. 2020;26(4):1–14.
  • Waqas H, Khan SA, Bhatti MM, et al. Bioconvection mechanism using third-grade nanofluid flow with Cattaneo–Christov heat flux model and Arrhenius kinetics. Int J Modern Phys B. 2021;35(17):2150178.
  • Zhang L, Bhatti MM, Shahid A, et al. Nonlinear nanofluid fluid flow under the consequences of Lorentz forces and Arrhenius kinetics through a permeable surface: a robust spectral approach. J Taiwan Inst Chem Eng. 2021;124:98–105.
  • Rafiq K, Irfan M, Khan M, et al. Arrhenius activation energy theory in radiative flow of Maxwell nanofluid. Phys Scr. 2021;96(4):045002.
  • Shoaib M, Nisar KS, Raja MAZ, et al. Intelligent networks knacks for numerical treatment of three-dimensional Darcy–Forchheimer Williamson nanofluid model past a stretching surface. Waves Rand Complex Media. 2022;1–29. DOI:10.1080/17455030.2022.2058713
  • Khan MN, Nadeem S. Consequences of Darcy–Forchheimer and Cattaneo–Christov on a radiative three-dimensional Maxwell fluid flow over a vertical surface. J Taiwan Inst Chem Eng. 2021;118:1–11.
  • Muhammad T, Waqas H, Khan SA, et al. Significance of nonlinear thermal radiation in 3D Eyring–Powell nanofluid flow with Arrhenius activation energy. J Therm Anal Calorim. 2021;143(2):929–944.
  • Raja MAZ, Shoaib M, Khan Z, et al. Supervised neural networks learning algorithm for three dimensional hybrid nanofluid flow with radiative heat and mass fluxes. Ain Shams Eng J. 2021;13(2): 101573.
  • Naveen Kumar R, Mallikarjuna HB, Tigalappa N, et al. Carbon nanotubes suspended dusty nanofluid flow over stretching porous rotating disk with non-uniform heat source/sink. Int J Comput Methods Eng Sci Mech. 2022;23(2):119–128.
  • Shoaib M, Kausar M, Sooppy Nisar K, et al. The design of intelligent networks for entropy generation in ree-eyring dissipative fluid flow system along quartic autocatalysis chemical reactions. Int J Heat Mass Transf. 2022;133:105971.
  • Wang F, Rani SP, Sarada K, et al. The effects of nanoparticle aggregation and radiation on the flow of nanofluid between the gap of a disk and cone. Case Stud Thermal Eng. 2022;33:101930.
  • Kotha G, Kolipaula VR, Rao MVS, et al. Internal heat generation on bioconvection of an MHD nanofluid flow due to gyrotactic microorganisms. Eur Phys J Plus. 2020;135(7):1–19.
  • Yusuf TA, Naveen Kumar R, Punith Gowda RJ, et al. Entropy generation on flow and heat transfer of a reactive MHD Sisko fluid through inclined walls with porous medium. Int J Ambient Energy. 2021;1–10. DOI:10.1080/01430750.2021.2013941
  • Sowmya G, Saleh B, Punith Gowda RJ, et al. (2021). Analysis of radiative nonlinear heat transfer in a convective flow of dusty fluid by capitalizing a non-Fourier heat flux model. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering. DOI:10.1177/09544089211041192
  • Naveen Kumar R, Saleh B, Abdelrhman Y, et al. Soret and Dufour effects on Oldroyd-B fluid flow under the influences of convective boundary condition with Stefan blowing effect. Indian J Phys. 2022;1–8. DOI:10.1007/s12648-022-02316-0
  • Shoaib M, Khan RA, Ullah H, et al. Heat transfer impacts on maxwell nanofluid flow over a vertical moving surface with mhd using stochastic numerical technique via artificial neural networks. Coatings. 2021;11(12):1483.
  • Alzahrani F, Gowda RP, Kumar RN, et al. Dynamics of thermosolutal Marangoni convection and nanoparticle aggregation effects on Oldroyd-B nanofluid past a porous boundary with homogeneous-heterogeneous catalytic reactions. J Indian Chem Soc. 2022;99(6):100458
  • Li YX, Khan MI, Gowda RP, et al. Dynamics of aluminum oxide and copper hybrid nanofluid in nonlinear mixed Marangoni convective flow with entropy generation: applications to renewable energy. Chin J Phys. 2021;73:275–287.
  • Wang F, Asjad MI, Zahid M, et al. Unsteady thermal transport flow of Casson nanofluids with generalized Mittag–Leffler kernel of Prabhakar’s type. J Mater Res Technol. 2021;14:1292–1300.
  • Casson N. A flow equation for pigment-oil suspensions of the printing ink type, Rheology of disperse systems, 1959
  • Gireesha BJ, Archana M, Mahanthesh B, et al. Exploration of activation energy and binary chemical reaction effects on nano Casson fluid flow with thermal and exponential space-based heat source. Multidiscipline Model Mater Struct. 2019;15(4):227–245.
  • Shoaib M, Raja MAZ, Khan MAR, et al. Neuro-Computing Networks for Entropy Generation under the Influence of MHD and Thermal Radiation. Surf Interfaces. 2021;25:101243.
  • Soumya DO, Gireesha BJ, Venkatesh P, et al. Effect of NP shapes on Fe3O4–Ag/kerosene and Fe3O4–Ag/water hybrid nanofluid flow in suction/injection process with nonlinear-thermal-radiation and slip condition; Hamilton and Crosser’s model. Waves Rand Complex Media. 2022;1–22. DOI:10.1080/17455030.2021.2022813
  • Ragupathi P, Muhammad T, Islam S, et al. Application of Arrhenius kinetics on MHD radiative Von Kármán Casson nanofluid flow occurring in a Darcy-Forchheimer porous medium in the presence of an adjustable heat source. Phys Scr. 2021;96(12):125228.
  • Kumar A, Tripathi R, Singh R, et al. Entropy generation on double diffusive MHD Casson nanofluid flow with convective heat transfer and activation energy. Indian J Phys. 2021;95(7):1423–1436.
  • Jayaprakash MC, Alsulami MD, Shanker B, et al. Investigation of Arrhenius activation energy and convective heat transfer efficiency in radiative hybrid nanofluid flow. Waves Rand Complex Media. 2022;1–13. DOI:10.1080/17455030.2021.2022811
  • Fayz-Al-Asad M, Alam MN, Ahmad H, et al. Impact of a closed space rectangular heat source on natural convective flow through triangular cavity. Results Phys. 2021;23:104011.
  • Asogwa KK, Alsulami MD, Prasannakumara BC, et al. Double diffusive convection and cross diffusion effects on Casson fluid over a Lorentz force driven Riga plate in a porous medium with heat sink: an analytical approach. Int J Heat Mass Transf. 2022;131:105761.
  • Raja MAZ, Tabassum R, El-Zahar ER, et al. Intelligent computing through neural networks for entropy generation in MHD third-grade nanofluid under chemical reaction and viscous dissipation. Waves Rand Complex Media. 2022;1–25. 10.1080/17455030.2022.2044095
  • Prasannakumara BC. Numerical simulation of heat transport in Maxwell nanofluid flow over a stretching sheet considering magnetic dipole effect. Partial Diff Equat Appl Math. 2021;4:100064.
  • Prasannakumara BC, Krishnamurthy MR, Gireesha BJ, et al. Effect of multiple slips and thermal radiation on MHD flow of Jeffrey nanofluid with heat transfer. J. Nanofluids. 2016;5(1):82–93
  • Prasannakumara BC. Assessment of the local thermal non-equilibrium condition for nanofluid flow through porous media: a comparative analysis. Indian J Phys. 2021;1–9. DOI:10.1007/s12648-021-02216-9
  • Kumar KG, Gireesha BJ, Kumara BC, et al. Impact of chemical reaction on marangoni boundary layer flow of a Casson nano liquid in the presence of uniform heat source sink. In: Diffusion Foundations. Vol. 11. Trans Tech Publications Ltd; 2017. p. 22–32.
  • Shoaib M, Kausar M, Khan MI, et al. Intelligent backpropagated neural networks application on Darcy-Forchheimer ferrofluid slip flow system. Int J Heat Mass Transf. 2021;129:105730.
  • Rekha MB, Sarris IE, Madhukesh JK, et al. Activation energy impact on Flow of AA7072-AA7075/water-based hybrid nanofluid through a cone, wedge and plate. Micromachines. 2022;13(2):302.
  • Madhukesh JK, Shankaralingappa BM, Gireesha BJ, et al. (2022). Evaluation of heat and mass transfer characteristics in a nanofluid flow over an exponentially stretchable sheet with activation energy. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering. DOI:10.1177/09544089221074827
  • Sowmya G, Gireesha BJ, Sindhu S, et al. Investigation of Ti6Al4V and AA7075 alloy embedded nanofluid flow over longitudinal porous fin in the presence of internal heat generation and convective condition. Commun Theor Phys. 2020;72(2):025004.
  • Sowmya G, Gireesha BJ, Prasannakumara BC. Scrutinization of different shaped nanoparticle of molybdenum disulfide suspended nanofluid flow over a radial porous fin. Int J Numer Methods Heat Fluid Flow. 2020;30(7):3685–3699. DOI:10.1108/HFF-08-2019-0622
  • Shamshuddin MD, Mabood F, Bég OA. Thermomagnetic reactive ethylene glycol-metallic nanofluid transport from a convectively heated porous surface with Ohmic dissipation, heat source, thermophoresis and Brownian motion effects. Int J Model Simulat. 2021;1–15. DOI:10.1080/02286203.2021.197753
  • Gowda RP, Mallikarjuna HB, Prasannakumara BC, et al. Dynamics of thermal Marangoni stagnation point flow in dusty Casson nanofluid. Int J Model Simulat. 2021;1–9. DOI:10.1080/02286203.2021.1957330
  • Fatunmbi EO, Salawu SO. Analysis of hydromagnetic micropolar nanofluid flow past a nonlinear stretchable sheet and entropy generation with Navier slips. Int J Model Simulat. 2022;42(3):359–369.
  • Abro KA, Atangana A. Strange attractors and optimal analysis of chaotic systems based on fractal versus fractional differential operators. Int J Model Simulat. 2021;1–9. DOI:10.1080/02286203.2021.1966729
  • Shamshuddin MD, Salawu SO, Bég OA, et al. Computation of reactive mixed convection radiative viscoelastic nanofluid thermo-solutal transport from a stretching sheet with Joule heating. Int J Model Simulat. 2021;1–25. DOI:10.1080/02286203.2021.2012635
  • Manohar GR, Venkatesh P, Gireesha BJ, et al. Performance of water, ethylene glycol, engine oil conveying SWCNT-MWCNT nanoparticles over a cylindrical fin subject to magnetic field and heat generation. Int J Model Simulat. 2021;1–10. DOI:10.1080/02286203.2021.2004296
  • Shamshuddin MD, Ibrahim W. Finite element numerical technique for magneto-micropolar nanofluid flow filled with chemically reactive Casson fluid between parallel plates subjected to rotatory system with electrical and Hall currents. Int J Model Simulat. 2022;1–20. DOI:10.1080/02286203.2021.2012634
  • Abro KA, Souayeh B, Malik K, et al. Chaotic characteristics of thermal convection at smaller verse larger Prandtl number through fractal and fractional differential operators from nanofluid. Int J Model Simulat. 2022;1–12. DOI:10.1080/02286203.2021.2018261
  • Patil AB, Patil VS, Humane PP, et al. Double diffusive time-dependent MHD Prandtl nanofluid flow due to linear stretching sheet with convective boundary conditions. Int J Model Simulat. 2022;1–15. DOI:10.1080/02286203.2022.2033499
  • Johnson A, B. I, B. I O. Impact of radiation and heat generation/absorption in a Walters’ B fluid through a porous medium with thermal and thermo diffusion in the presence of chemical reaction. Int J Model Simulat. 2022;1–14. 10.1080/02286203.2022.2035948
  • Ali Y, Afzal Rana M, Shoaib M. Three dimensional second grade fluid flow between two parallel horizontal plates with periodic suction/injection in slip flow regime. Punjab Univ J Math. 2020;50(4):133–145.
  • Waseem W, Sulaiman M, Kumam P, et al. Investigation of singular ordinary differential equations by a neuroevolutionary approach. PLoS One. 2020;15(7):e0235829.
  • Rashid U, Abdeljawad T, Liang H, et al. The Shape Effect of Gold Nanoparticles on Squeezing Nanofluid Flow and Heat Transfer between Parallel Plates. Math Prob Eng. 2020;2020. DOI:10.1155/2020/9584854
  • Imran A, Akhtar R, Zhiyu Z, et al. Analysis of MHD and heat transfer effects with variable viscosity through ductus efferentes. AIP Adv. 2019;9(8):085320.
  • Khan WA, Waqas M, Chammam W, et al. Evaluating the characteristics of magnetic dipole for shear-thinning Williamson nanofluid with thermal radiation. Comput Methods Programs Biomed. 2020;191:105396.
  • Sabir Z, Raja MAZ, Umar M, et al. Design of neuro-swarming-based heuristics to solve the third-order nonlinear multi-singular Emden–Fowler equation. Eur Phys J Plus. 2020;135(5):410.
  • Awais M, Awan SE, Raja MAZ, et al. Effects of Gyro-Tactic organisms in bio-convective nano-material with heat immersion, stratification, and viscous dissipation. Arab J Sci Eng. 2021;46(6):5907–5920.
  • Sabir Z, Raja MAZ, Umar M, et al. FMNSICS: fractional Meyer neuro-swarm intelligent computing solver for nonlinear fractional Lane–Emden systems. Neural Comput Appl. 2022;34(6):4193–4206.
  • Sabir Z, Raja MAZ, Guirao JL, et al. Integrated intelligent computing with neuro-swarming solver for multi-singular fourth-order nonlinear Emden–Fowler equation. Comput Appl Math. 2020;39(4):1–18.
  • Ullah H, Khan I, Fiza M, et al. MHD boundary layer flow over a stretching sheet: a new stochastic method. Math Prob Eng. 2021;2021. DOI:10.1155/2021/9924593
  • Wakif A, Animasaun IL, Khan U, et al. Insights into the generalized fourier’s and fick’s laws for simulating mixed bioconvective flows of radiative-reactive Walters-b fluids conveying tiny particles subject to Lorentz force. 2021. DOI:10.21203/rs.3.rs-398087/v1
  • Upadhya SM, Devi RR, Raju CSK, et al. Magnetohydrodynamic nonlinear thermal convection nanofluid flow over a radiated porous rotating disk with internal heating. J Therm Anal Calorim. 2021;143(3):1973–1984.
  • Ullah I, Ullah R, Alqarni MS, et al. Combined heat source and zero mass flux features on magnetized nanofluid flow by radial disk with the applications of Coriolis force and activation energy. Int J Heat Mass Transf. 2021;126:105416.
  • Rosseland SS-V, Berlin. Astrophysik und atom-theoretische Grundlagen.[Google Scholar]. 1931. p. 41–44.
  • Von Kármán T. Uber laminare und turbulente Reibung. Z Angew Math Mech. 1921;1(4):233–252
  • Shoaib M, Raja MAZ, Zubair G, et al. Intelligent computing with levenberg–Marquardt backpropagation neural networks for third-grade nanofluid over a stretched sheet with convective conditions. Arab J Sci Eng. 2021;1–19. 10.1007/s13369-021-06202-5
  • Uddin I, Ullah I, Raja MAZ, et al. Design of intelligent computing networks for numerical treatment of thin film flow of Maxwell nanofluid over a stretched and rotating surface. Surf Interfaces. 2021;24:101107.
  • Khan RA, Ullah H, Asif Zahoor Raja M, et al. Heat transfer between two porous parallel plates of steady nano fluids with brownian and thermophoretic effects: a new stochastic numerical approach. Int J Heat Mass Transf. 2021;126:105436.
  • Raja MAZ, Malik MF, Chang CL, et al. Design of backpropagation networks for bioconvection model in transverse transportation of rheological fluid involving Lorentz force interaction and gyrotactic microorganisms. J Taiwan Inst Chem Eng. 2021;121:276–291.
  • Akhtar R, Awais M, Raja MAZ, et al. Analytical treatment for the dynamics of second law analysis of Jeffrey nanofluid with convective heat and mass conditions. J Nanoelectron Optoelectron. 2021;16(1):89–96.
  • Shoaib M, Kausar M, Khan MI, et al. Intelligent backpropagated neural networks application on Darcy-Forchheimer ferrofluid slip flow system. Int J Heat Mass Transf. 2021;129:105730.
  • Waqas H, Farooq U, Bhatti MM, et al. Magnetized bioconvection flow of Sutterby fluid characterized by the suspension of nanoparticles across a wedge with activation energy. ZAMM Z Angew Math Mech. 2021: e202000349
  • Umar M, Raja MAZ, Sabir Z, et al. A stochastic computational intelligent solver for numerical treatment of mosquito dispersal model in a heterogeneous environment. Eur Phys J Plus. 2020;135(7):1–23.
  • Sabir Z, Raja MAZ, Umar M, et al. Design of neuro-swarming-based heuristics to solve the third-order nonlinear multi-singular Emden–Fowler equation. Eur Phys J Plus. 2020;135(5):410.
  • Raja MAZ, Shoaib M, Hussain S, et al. Computational intelligence of Levenberg-Marquardt backpropagation neural networks to study thermal radiation and Hall effects on boundary layer flow past a stretching sheet. Int J Heat Mass Transf. 2022;130:105799.
  • Awan SE, Raja MAZ, Gul F, et al. Numerical computing paradigm for investigation of micropolar nanofluid flow between parallel plates system with impact of electrical MHD and Hall current. Arab J Sci Eng. 2021;46(1):645–662.

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