https://doi.org/10.65770/THFY9389
ABSTRACT
This work finds application in micro-fabrication techniques and the chemical industry. This study examines the effects of the magnetic field and electroosmotic repulsion on the peristaltic flow of a third-grade nanofluid in an asymmetric channel. The problem is modelled with the aid of a lubrication approach. The expressions for stream function, velocity, temperature, and species concentration are derived using the Adomian decomposition method. The physical parameters are analyzed and discussed graphically. The significant outcome of this work is to analyze the flow behaviour in both symmetric and asymmetric channels. The results are used to analyze the blood flow through channels, which helps examine the artery blockage treatment and cancer tumour elimination. The velocity profile with the impact of Deborah’s number and the electroosmotic parameter is studied for both channels. Validation of obtained results is done in comparison with the previous results.
References
- [1] Chakraborty, S. Augmentation of peristaltic microflows through electro-osmotic mechanisms. J. Phys. D Appl. Phys. (2006) 39, 5356.
- [2] Abbasi A., Mabood F., Farooq W., Khan SU.Radiation and joule heating effects on electroosmosis-modulated peristaltic flow of Prandtl nanofluid via tapered channel Int Commun Heat Mass Transf, (2021) 123, 105183.
- [3] Akram J., Akbar N S., Maraj EN. A comparative study on the role of nanoparticle dispersion in electroosmosis regulated peristaltic flow of water. Alex Eng J, 59 (2020), pp. 943-956
- [4] Mabood F., Farooq W., AbbasiA .Entropy generation analysis in the electro-osmosis-modulated peristaltic flow of Eyring–Powell fluid. J Therm AnalCalorim (2021) 1007/s10973-021-10736-z.
- [5] Jayavel P., Jhorar R., Tripathi D., Azese MN. Electroosmotic flow of pseudoplastic nanoliquids via peristaltic pumping. J Braz Soc Mech Sci, (2019) 41:61.
- [6] Prasanth Reddy and M. V. Subba Reddy, “Peristaltic pumping of a third grade fluid in an asymmetric channel under the effect of magnetic field” Adv. Appl. Sci. Res, 3(6) (2012) 3868-3877.
- [7] Hayat and O.U. Mehmood, “Slip effects on MHD flow of third order fluid in a planar channel” Comm nonlinear Sci Num Simulation, 16, (2011) 1363–1377.
- [8] W. Latham, Fluid Motions in a Peristaltic Pump (M.S. Thesis) MIT, Cambridge, MA, (1996).
- [9] H. Shapiro, M.Y. Jaffrey, S.L. Weinberg, Peristaltic pumping with long wavelengths at low Reynolds number, J. Fluid Mech. 37, pp.799-825 (1969).
- Hayat, F.M. Abbasi, A. Alsaedi, F. Alsaedi, Hall and Ohmic heating effects on the peristaltic Transport of Carreau-Yasuda fluid in an asymmetric channel, Z. Naturforsch., pp. 43-51 (2013).
- S. Mekheimer, Y.A. Elmaboud, A.I. Abdellateef, Peristaltic transport through eccentric Cylinders: Mathematical model, Appl. Bionics Biomech. 10, pp.19-27 (2013).
- Hayat, A. Tan veer, H. Yasmin, A. Alsaedi, Effects of convective conditions and chemical Reaction on peristaltic flow of Eyring-Powell fluid, Appl. Bionics Biomech.11, pp. 221-233 (2014).
- Hayat, H. Yasmin, B. Ahmad, B. Chen, Simultaneous effects of convective conditions and Nanoparticles on peristaltic motion. J. Mol. Liq. 193, pp. 74-82 (2014).
- Kothandapani and S. Srinivas, “Nonlinear peristaltic transport of a Newtonian fluid in an inclined asymmetric channel through a porous medium”, Phys. Lett. A, 372 (2008) 1265-1276.
- P. Rathod and Laxmi Devindrappa, “Peristaltic transport in an inclined asymmetric channel with heat and mass transfer by Adomian decomposition method” Adv in Applied Sci and Research, 7 (2016) 83-100.
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