In electrochemical reactions, cellular processes, and drug design the application of activation energy is important. However, continuous metal casting in industries for polymer extrusion in metal spinning, the flow of nanofluid with activation energy over a stretching surface plays crucial role. Based on the constructive recent applications, the current investigation focuses on the magnetohydrodynamic radiative flow of nanofluid over an elongating sheet, examining the effects of inertial drag and Arrhenius activation energy. Moreover, the significance of Thermophoresis and Brownian motion in the two-phase nanofluid model is crucial owing to their involvement in the cross-diffusion process. The implementation of similarity rules, the transport phenomena along with surface conditions are normalised and then the system involved with characterizing parameters are handled numerically. In particular, Rung-Kutta shooting is adopted with the help of built-in routine code bvp4c in MATLAB for the solution. Although the computational numerical result of the rate coefficient is used for the validation, the parametric analysis is presented graphically. Finally, the major contribution of the factors to the flow phenomena is stated as follows: cross-diffusion caused by Brownian motion causes the development of both temperature and concentration distributions, whereas thermophoresis has unique consequences. Furthermore, the Lewis number and chemical reactions are critical criteria that must be addressed, when managing the concentration distribution.
ChoiSUSEastmanJA. Enhancing thermal conductivity of fluids with nanoparticles. In: The proceedings of the 1995 ASME international mechanical engineering congress and exposition, vol. 66, ASME, FED 231/MD, San Francisco, 1995, pp.99–105.
2.
KumarDDArasuAV. A comprehensive review of preparation, characterisation, properties and stability of hybrid nanofluids. Renew Sustain Energy Rev2018; 81: 1669–1689.
3.
SureshSVenkitarajKPSelvakumarP, et al. Synthesis of Al2O3–Cu/water hybrid nanofluids using two step method and its thermo physical properties. Colloids Surf A Physicochem Eng Asp2011; 388: 41–48.
4.
MominGG. Experimental investigation of mixed convection with water-Al2O3 and hybrid nanofluid in inclined tube for laminar flowInt J Sci Technol Res2013; 2: 195–202.
5.
AsadiAAlarifiIMFoongLK. An experimental study on characterisation, stability and dynamic viscosity of CuO-TiO2/water hybrid nanofluid. J Mol Liq2020; 307: 112987.
6.
GangadharKLakshmiKBKannanT. Thermal transport of magnetised Cu-Fe 3 O 4/water hybrid nanofluid over a curved surface. Int J Appl Comput Math2021; 7: 191.
7.
BoroomandpourAToghraieDHashemianM. A comprehensive experimental investigation of thermal conductivity of a ternary hybrid nanofluid containing MWCNTs- titania-zinc oxide/water-ethylene glycol (80:20) as well as binary and mono nanofluids. Synth Met2020; 268: 116501.
8.
Srinivas ReddyCMahantheshBRanaP, et al. Entropy generation analysis of tangent hyperbolic fluid in quadratic Boussinesq approximation using spectral quasi-linearisation method. Appl Math Mech-Engl Ed2021; 42: 1525–1542.
9.
AwanAUAliBShahSAA, et al. Numerical analysis of heat transfer in Ellis hybrid nanofluid flow subject to a stretching cylinder. Case Stud Therm Eng2023; 49: 103222.
10.
LiSAkbarSSohailM, et al. Influence of buoyancy and viscous hybrid nanofluid (MgO – TiO2) under slip conditions. Case Stud Therm Eng2023; 49: 103281.
11.
VedavathiNDharmaiahGVenkatadriK, et al. Numerical study of radiative non-Darcy nanofluid flow over a stretching sheet with a convective Nield conditions and energy activation. Nonlinear Eng2021; 10: 159–176.
12.
Veera KrishnaMAhammadNAChamkhaAJ. Radiative MHD flow of Casson hybrid nanofluid over an infinite exponentially accelerated vertical porous surface. Case Stud Therm Eng2021; 27: 101229.
13.
MadhuMKishanNChamkhaAJ. Unsteady flow of a Maxwell nanofluid over a stretching surface in the presence of magnetohydrodynamic and thermal radiation effects. Propuls Power Res2017; 6: 31–40.
14.
ManjunathaSPuneethVGireeshaBJ, et al. Theoretical study of convective heat transfer in ternary nanofluid flowing past a stretching sheet. J Appl Comput Mech2022; 8: 1279–1286.
15.
ManjunathaSAmmani KuttanBJayanthiS, et al. Heat transfer enhancement in the boundary layer flow of hybrid nanofluids due to variable viscosity and natural convection. Heliyon2019; 5: e01469.
16.
GorlaRSRChamkhaA. Natural convective boundary layer flow over a nonisothermal vertical plate embedded in a porous medium saturated with a nanofluid. Nanoscale Microscale Thermophys Eng2011; 15: 81–94.
17.
ShafiqAÇolakABSindhuTN, et al. Estimation of unsteady hydromagnetic Williamson fluid flow in a radiative surface through numerical and artificial neural network modeling. Sci Rep2021; 11: 14509.
18.
HayatTShafiqAAlsaediA. MHD axisymmetric flow of third grade fluid by a stretching cylinder. Alexandria Eng J2015; 54: 205–212.
19.
ShafiqAÇolakABSindhuTN. Modeling of soret and dufour’s convective heat transfer in nanofluid flow through a moving needle with artificial neural network. Arab J Sci Eng2023; 48: 2807–2820.
20.
NaseemFShafiqAZhaoL, et al. MHD biconvective flow of powell eyring nanofluid over stretched surface. AIP Adv2017; 7: 065013.
21.
ShafiqAÇolakABSindhuTN. Comparative analysis to study the Darcy–Forchheimer Tangent hyperbolic flow towards cylindrical surface using artificial neural network: an application to Parabolic Trough Solar Collector. Math Comput Simul2024; 216: 213–230.
22.
BaagSPandaSPattnaikPK, et al. Free convection of conducting nanofluid past an expanding surface with heat source with convective heating boundary conditions. Int J Ambient Energy2023; 44: 880–891.
23.
PandaSOntelaSThummaT, et al. Mechanism of heat transfer in Falkner–Skan flow of buoyancy-driven dissipative hybrid nanofluid over a vertical permeable wedge with varying wall temperature. Mod Phys Lett B2024; 38: 2350211.
24.
KhanWA. Significance of magnetised Williamson nanofluid flow for ferromagnetic nanoparticles. Waves Random Complex Media. Epub ahead of print 3May2023. DOI: 10.1080/17455030.2023.2207390.
25.
Azeem KhanW. Impact of time-dependent heat and mass transfer phenomenon for magnetised Sutterby nanofluid flow. Waves Random Complex Media. Epub ahead of print 20November2022. DOI: 10.1080/17455030.2022.2140857.
26.
KhanWA. Dynamics of gyrotactic microorganisms for modified Eyring Powell nanofluid flow with bioconvection and nonlinear radiation aspects. Waves Random Complex Media. Epub ahead of print 1February2023. DOI: 10.1080/17455030.2023.2168086.
27.
IrfanMKhanWAPashaAA, et al. Significance of non-Fourier heat flux on ferromagnetic Powell-Eyring fluid subject to cubic autocatalysis kind of chemical reaction. Int Commun Heat Mass Transf2022; 138: 106374.
28.
AnjumNKhanWAHobinyA, et al. Numerical analysis for thermal performance of modified Eyring Powell nanofluid flow subject to activation energy and bioconvection dynamic. Case Stud Therm Eng2022; 39: 102427.
29.
SharmaJAmeer AhammadNWakifA, et al. Solutal effects on thermal sensitivity of casson nanofluids with comparative investigations on Newtonian (water) and non-Newtonian (blood) base liquids. Alexandria Eng J2023; 71: 387–400.
30.
ZhangKShahNAAlshehriM, et al. Water thermal enhancement in a porous medium via a suspension of hybrid nanoparticles: MHD mixed convective Falkner’s-Skan flow case study. Case Stud Therm Eng2023; 47: 103062.
31.
RagupathiPAhammadNAWakifA, et al. Exploration of multiple transfer phenomena within viscous fluid flows over a curved stretching sheet in the co-existence of gyrotactic micro-organisms and tiny particles. Math2022; 10: 4133.
32.
ShahNAWakifAShahR, et al. Effects of fractional derivative and heat source/sink on MHD free convection flow of nanofluids in a vertical cylinder: a generalised Fourier’s law model. Case Stud Therm Eng2021; 28: 101518.
33.
WakifAAlshehriAMuhammadT. Influences of blowing and internal heating processes on steady MHD mixed convective boundary layer flows of radiating titanium dioxide-ethylene glycol nanofluids. ZAMM Zeitschrift Fur Angew Math Und Mech2024; 104: e202300536.
