WangCY. Axisymmetric stagnation flow on a cylinder. Quarterly of Applied Mathematics1974; 32: 207–213.
2.
MoffattHK. Behaviour of a viscous film on the outer surface of a rotating cylinder. Journal de Mecanique1977; 16: 651–673.
3.
GorlaRSR. Non-similar axisymmetric stagnation flow on a moving cylinder. Int J Eng Sci1978; 16: 392–400.
4.
KunetsYI. Axisymmetric torsion of an elastic space with a thin elastic inclusion. Journal of Applied Mathematics and Mechanics1987; 51: 497–503.
5.
CunningGMDavisAMJWeidmanPD. Radial stagnation flow on a rotating circular cylinder with uniform transpiration. J Eng Math1998; 33: 113–128.
6.
SpragueMAWeidmanPD. Three-dimensional flow induced by the torsional motion of a cylinder. Fluid Dyn Res2010; 43: 015501.
7.
FangTYaoS. Viscous swirling flow over a stretching cylinder. Chin Phys Lett2011; 28: 114702.
8.
KnyazevDV. Axisymmetric flows of an incompressible fluid between movable rotating disks. Fluid Dynamics2011; 46: 558.
9.
MastroberardinoASiddiqueJI. Magnetohydrodynamic stagnation flow and heat transfer toward a stretching permeable cylinder. Advances in Mechanical Engineering2014; 6: 419568.
10.
TurnerMRWeidmanP. The boundary layer flow induced above the torsional motion of a disk. Phys Fluids2019; 31: 043604.
11.
RiveroMGarzónFNúñezJ,et al.Study of the flow induced by circular cylinder performing torsional oscillation. European Journal of Mechanics-B/Fluids2019; 78: 245–251.
ChoiSUEastmanJA. Enhancing thermal conductivity of fluids with nanoparticles. Developments and Applications of Non-Newtonian Flows1995; FED-vol. 231/MD-vol. 66: 99–105.
14.
XuanYLiQ. Heat transfer enhancement of nanofluids. International Journal of heat and fluid flow2000; 21: 58–64.
15.
JangSPChoiSU. Role of Brownian motion in the enhanced thermal conductivity of nanofluids. Appl Phys Lett2004; 84: 4316–4318.
16.
MohammadiunHRahimiABKianifarA. Axisymmetric stagnation-point flow and heat transfer of a viscous, compressible fluid on a cylinder with constant heat flux. Scientia Iranica2013; 20: 185–194.
17.
AshorynejadHRSheikholeslamiMPopI,et al.Nanofluid flow and heat transfer due to a stretching cylinder in the presence of magnetic field. Heat and Mass Transfer2013; 49: 427–436.
18.
SrinivasSReddyPBAPrasadBSRV. Effects of chemical reaction and thermal radiation on MHD flow over an inclined permeable stretching surface with non-uniform heat source/sink: an application to the dynamics of blood flow. J Mech Med Biol2014; 14: 1450067.
19.
MalvandiAHedayatiFGanjiDD. Slip effects on unsteady stagnation point flow of a nanofluid over a stretching sheet. Powder Technol2014; 253: 377–384.
20.
SheikholeslamiMAbelmanSGanjiDD. Numerical simulation of MHD nanofluid flow and heat transfer considering viscous dissipation. Int J Heat Mass Transfer2014; 79: 212–222.
21.
TurkyilmazogluM. MHD Fluid flow and heat transfer due to a shrinking rotating disk. Comput Fluids2014; 90: 51–56.
22.
PalDMandalG. Magnetohydrodynamic heat transfer of nanofluids past a stretching cylinder with non-uniform heat source/sink and chemical reaction. International Journal of Applied and Computational Mathematics2017; 3: 2889–2908.
23.
HayatTQayyumSAlsaediA,et al.Radiation effects on the mixed convection flow induced by an inclined stretching cylinder with non-uniform heat source/sink. PloS one2017; 12(4): e0175584. http://doi.org/10.1371/journal.pone.0175584
24.
AmbreenTKimMH. Heat transfer and pressure drop correlations of nanofluids: a state of art review. Renewable Sustainable Energy Rev2018; 91: 564–583.
25.
YangLHuangJNJiW,et al.Investigations of a new combined application of nanofluids in heat recovery and air purification. Powder Technol2020; 360: 956–966.
26.
HayatTKhanMIFarooqM,et al.Impact of cattaneo--christov heat flux model in flow of variable thermal conductivity fluid over a variable thicked surface. Int J Heat Mass Transfer2016; 99: 702–710.
27.
KhanMIWaqasMHayatT,et al.A comparative study of casson fluid with homogeneous-heterogeneous reactions. J Colloid Interface Sci2017; 498: 85–90.
28.
KhanMSarfrazMAhmedJ,et al.Non-axisymmetric homann stagnation-point flow of Walter's B nanofluid over a cylindrical disk. Applied Mathematics and Mechanics-English Edition2020; 41: 725–740. https://doi.org/10.1007/s10483-020-2611-5
29.
SahooBShevchukIV. Heat transfer due to revolving flow of reiner-rivlin fluid over a stretchable surface. Thermal Science and Engineering Progress2019; 10: 327–336.
30.
KhanMAhmedAAhmedJ. Boundary layer flow of Maxwell fluid due to torsional motion of cylinder: modeling and simulation. Applied Mathematics and Mechanics2020: 1–14.
31.
KhanMIAlzahraniF. Numerical simulation for the mixed convective flow of non-newtonian fluid with activation energy and entropy generation. Math Methods Appl Sci2020; 44(9): 7766–7777. doi.org/10.1002/mma.6919
32.
KhanMIAlzahraniF. Binary chemical reaction with activation energy in dissipative flow of non-newtonian nanomaterial. Journal of Theoretical and Computational Chemistry2020; 19: 2040006.
33.
KhanMIAlzahraniF. Transportation of heat through cattaneo-christov heat flux model in non-newtonian fluid subject to internal resistance of particles. Applied Mathematics and Mechanics2020; 41: 1157–1166.
34.
IbrahimMKhanMI. Mathematical modeling and analysis of SWCNT-water and MWCNT-water flow over a stretchable sheet. Comput Methods Programs Biomed2020; 187: 105222.
35.
KhanMIAlzahraniF. Entropy-optimized dissipative flow of carreau--yasuda fluid with radiative heat flux and chemical reaction. The European Physical Journal Plus2020; 135: 1–16.
36.
KhanMI. Transportation of hybrid nanoparticles in forced convective darcy-forchheimer flow by a rotating disk. International Communications in Heat and Mass Transfer2021; 122: 105177.
37.
KhanMIAlzahraniF. Nonlinear dissipative slip flow of jeffrey nanomaterial towards a curved surface with entropy generation and activation energy. Math Comput Simul2021; 185: 47–61.
38.
KhanMIAlzahraniF. Dynamics of activation energy and nonlinear mixed convection in darcy-forchheimer radiated flow of carreau nanofluid near stagnation point region. J Therm Sci Eng Appl2021; 13: 051009.
39.
KhanMIAlzahraniF. Free convection and radiation effects in nanofluid (silicon dioxide and molybdenum disulfide) with second order velocity slip, entropy generation, darcy-forchheimer porous medium. Int J Hydrogen Energy2021; 46: 1362–1369.
40.
KhanMIAlzahraniF. Cattaneo-Christov double diffusion (CCDD) and magnetized stagnation point flow of non-newtonian fluid with internal resistance of particles. Phys Scr2020; 95: 125002.
41.
ShahZHajizadehMRAlreshidiNA,et al.Entropy optimization and heat transfer modeling for lorentz forces effect on solidification of NEPCM. International Communications in Heat and Mass Transfer2020; 117: 104715.
42.
KhanAShahZAlzahraniE,et al.Entropy generation and thermal analysis for rotary motion of hydromagnetic casson nanofluid past a rotating cylinder with joule heating effect. International Communications in Heat and Mass Transfer2020; 119: 104979.
43.
SaeedATassaddiqAKhanA,et al.Darcy-Forchheimer MHD hybrid nanofluid flow and heat transfer analysis over a porous stretching cylinder. Coatings2020; 10: 391.
44.
SheikholeslamiMShahZShafeeA,et al.Lorentz force impact on hybrid nanofluid within a porous tank including entropy generation. International Communications in Heat and Mass Transfer2020; 116: 104635.
45.
ShahZDawarAIslamS. Influence of Brownian motion and thermophoresis parameters on silver-based Di-hydrogen CNTs between two stretchable rotating disks. Phys Scr2021; 96: 055205.
46.
LiYMKhanMIKhanSA,et al.An assessment of the mathematical model for estimating of entropy optimized viscous fluid flow towards a rotating cone surface. Sci Rep2021; 11: 1–15.
47.
BuongiornoJ. Convective transport in nanofluids. J Heat Transfer2006; 128: 240–250.
48.
WangCY. Fluid flow due to a stretching cylinder. Phys Fluids1988; 31: 466–468.
49.
MagyariEWeidmanPD. The preheated airy wall jet. Heat and mass transfer2005; 41: 1014–1020.
