Peristaltic rheology and thermal analysis of SWCNT-MWCNT/H 2 O hybrid nanofluid in a complex microchannel under electroosmotic effects

Abstract

The primary goal of this research is to investigate the rheology and heat transport of a hybrid nanofluid in an asymmetric microchannel in the presence of an electric field. The mobility of hybrid fluid is caused by peristaltic waves that contract and relax sinusoidally along the channel length. The rheological equations system is simplified by introducing relevant similarity variables, which are then solved using the integration approach. In this study, convective boundary conditions are applied. The electric potential function, velocity profile, pressure gradient, stream function, and temperature profile are all mathematically expressed. The current study’s findings are based on three physiological estimates: first is known as the creeping phenomenon, second as the greater wavelength condition, and third as the Debye–Hückel linearization (DHL). Using two different nanoparticles (SWCNT-MWCNT), the peristaltic mechanism is used to model water-based nanofluids. The three-dimensional graphs of rheological features are generated using Mathematica Software to elaborate the influences of relevant parameters on the rheological characteristics. By enhancing both the Biot number and the heat source/sink parameter in the hybrid fluid, the magnitudes of the temperature profile and the Nusselt number are higher than in the $(SWCNT / H_{2} O or MWCNT / H_{2} O)$ nanofluids. The magnitude of velocity profile is enhanced by increasing the Buoyancy forces and slip velocity. The results of simple fluid are obtained in the absence of concentration parameter. To boost the pumping phenomena, the special nature of peristaltic waves is used. The comparative study of nanofluid and hybrid fluid is also addressed. Three-dimensional graphs are plotted to clearly observe the influence of rheological parameters on flow features.

Keywords

Debye–Hückel linearization (DHL)complex peristaltic waves electroosmotic pumps hybrid nanofluid velocity and thermal slips lubrication theory asymmetric microchannel heat source/sink parameter

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References

Farina

Fusi

Fasano

, et al. Modeling peristaltic flow in vessels equipped with valves: Implications for vasomotion in bat wing venules. Int J Eng Sci 2016; 107: 1–12.

Klespitz

Kovacs

Peristaltic pumps—a review on working and control possibilities. In: 2014 IEEE 12th international symposium on applied machine intelligence and informatics (SAMI), 2014. New York: IEEE.

Shukla

Chandra

Sharma

, et al. Effects of peristaltic and longitudinal wave motion of the channel wall on movement of micro-organisms: application to spermatozoa transport. J Biomech 1988; 21: 947–954.

Onal

Wood

Rus

Towards printable robotics: Origami-inspired planar fabrication of three-dimensional mechanisms. In: 2011 IEEE international conference on robotics and automation, 2011. New York: IEEE.

Fauci

LJ.

Peristaltic pumping of solid particles. Comput Fluids 1992; 21: 583–598.

Fung

Yih

CS.

Peristaltic transport. J Appl Mech 1968; 35: 669–675.

Haroun

MH.

Non-linear peristaltic flow of a fourth grade fluid in an inclined asymmetric channel. Comput Mater Sci 2007; 39: 324–333.

Hayat

Qureshi

Ali

The influence of slip on the peristaltic motion of a third order fluid in an asymmetric channel. Phys Lett A 2008; 372: 2653–2664.

Ali

Javid

Sajid

, et al. Numerical simulation of peristaltic flow of a biorheological fluid with shear-dependent viscosity in a curved channel. Comput Methods Biomech Biomed Engin 2016; 19: 614–627.

10.

Tripathi

Anwar Bég

Transient magneto-peristaltic flow of couple stress biofluids: a magneto-hydro-dynamical study on digestive transport phenomena. Math Biosci 2013; 246: 72–83.

11.

Javid

Ali

Sajid

Simultaneous effects of viscoelasticity and curvature on peristaltic flow through a curved channel. Meccanica 2016; 51: 87–98.

12.

Xiong

P.-Y

Javid

Raza

, et al. MHD flow study of viscous fluid through a complex wavy curved surface due to bio-mimetic propulsion under porosity and second-order slip effects. Commun Theor Phys 2021; 73: 085001.

13.

Choi SUS, Eastman JA Enhancing thermal conductivity of fluids with nanoparticles. 1995. United States: N. p. https://www.osti.gov/biblio/196525

14.

Akram

Athar

Saeed

Hybrid impact of thermal and concentration convection on peristaltic pumping of Prandtl nanofluids in non-uniform inclined channel and magnetic field. Case Stud Therm Eng 2021; 25: 100965.

15.

Kothandapani

Prakash

Effect of radiation and magnetic field on peristaltic transport of nanofluids through a porous space in a tapered asymmetric channel. J Magn Magn Mater 2015; 378: 152–163.

16.

Nie

Marlow

Hassan

YA.

Discussion of proposed mechanisms of thermal conductivity enhancement in nanofluids. Int J Heat Mass Transf 2008; 51: 1342–1348.

17.

Sadaf

Abdelsalam

SI.

Adverse effects of a hybrid nanofluid in a wavy non-uniform annulus with convective boundary conditions. RSC Adv 2020; 10: 15035–15043.

18.

Farooq

Ijaz Khan

Waqas

, et al. Transport of hybrid type nanomaterials in peristaltic activity of viscous fluid considering nonlinear radiation, entropy optimization and slip effects. Comput Methods Programs Biomed 2020; 184: 105086.

19.

Akbar

Akram

Aun

, et al. MHD peristaltic transportation of radiative MWCNT-Ag/CHO hybrid nanofluid with variable characteristics. Mater Today Commun 2021; 28: 102681.

20.

Sheriff

Ahmad

Mir

NA.

Irreversibility effects in peristaltic transport of hybrid nanomaterial in the presence of heat absorption. Sci Rep 2021; 11: 19697.

21.

Ahmed

Hayat

Alsaedi

Mixed convection peristalsis of hybrid nanomaterial flow in thermally active symmetric channel. Case Stud Therm Eng 2021; 27: 101272.

22.

Ahmed

Rashed

ZZ.

Magnetohydrodinamic dusty hybrid nanofluid peristaltic flow in curved channels. Therm Sci 2021; 25: 4241–4255.

23.

Nuwairan

Souayeh

Simulation of gold nanoparticle transport during MHD electroosmotic flow in a peristaltic micro-channel for biomedical treatment. Micromachines (Basel) 2022; 13: 374.

24.

Hussain

Wang

Akbar

, et al. Enhanced thermal effectiveness for electroosmosis modulated peristaltic flow of modified hybrid nanofluid with chemical reactions. Sci Rep 2022; 12: 13756.

25.

Tripathi

Prakash

Gnaneswara Reddy

, et al. Numerical study of electroosmosis-induced alterations in peristaltic pumping of couple stress hybrid nanofluids through microchannel. Indian J Phys Proc Indian Assoc Cultiv Sci (2004) 2021; 95: 2411–2421.

26.

Farooq

Khan

Riahi

, et al. Modeling and interpretation of peristaltic transport in single wall carbon nanotube flow with entropy optimization and Newtonian heating. Comput Methods Programs Biomed 2020; 192: 105435.

27.

Abbasi

Zahid

Akbar

, et al. Thermodynamic analysis of electroosmosis regulated peristaltic motion of Fe3O4 -Cu/H2O hybrid nanofluid. Int J Mod Phys B; 2022; 36: 2250060.

28.

Mahanthesh

Gireesha

Animasaun

, et al. MHD flow of SWCNT and MWCNT nanoliquids past a rotating stretchable disk with thermal and exponential space dependent heat source. Phys Scr 2019; 94: 085214.

29.

Faisal Javed

Khan

, et al. Optimization of SWCNTs and MWCNTs (single and multi-wall carbon nanotubes) in peristaltic transport with thermal radiation in a non-uniform channel. J Mol Liq 2019; 273: 383–391.

30.

Brinkman

HC.

The viscosity of concentrated suspensions and solutions. J Chem Phys 1952; 20: 571–571.

31.

Javid

Waqas

Asghar

, et al. A theoretical analysis of biorheological fluid flowing through a complex wavy convergent channel under porosity and electro-magneto-hydrodynamics effects. Comput Methods Programs Biomed 2020; 191: 105413.

32.

Prakash

Tripathi

Bég

OA.

Comparative study of hybrid nanofluids in microchannel slip flow induced by electroosmosis and peristalsis. Appl Nanosci 2020; 10: 1693–1706.

33.

Awais

Hayat

Ali

, et al. Velocity, thermal and concentration slip effects on a magneto-hydrodynamic nanofluid flow. Alex Eng J 2016; 55: 2107–2114.

34.

Dero

Abdelhameed

Al-Khaled

, et al. Contribution of suction phenomenon and thermal slip effects for radiated hybrid nanoparticles (Al₂O₃−Cu/H₂O) with stability framework. Int J Mod Phys B 2023; 37: 2350147.