MHD Casson nanofluid flow in a square enclosure with non-uniform heating using the Brinkman model

Yasmin, Asia; Ali, Kashif; Ashraf, Muhammad

doi:10.1140/epjp/s13360-021-01093-9

Cited by 13 publications

(3 citation statements)

References 37 publications

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“…We compare our numerical results for the horizontal velocity profiles (for the special case when

= 0,

= 0, and only one moving lid drives the flow), along the three different horizontal lines (y = 0.25, 0.5, 0.75), with the ones given by Asia et al [ 35 ] to verify the accuracy of our numerical procedure. Fig.…”

Section: Validation Of Our Numerical Schemementioning

confidence: 89%

Vortex generation due to multiple localized magnetic fields in the hybrid nanofluid flow – A numerical investigation

Ahmad¹,

Ali²,

Katbar³

et al. 2023

Heliyon

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“…We compare our numerical results for the horizontal velocity profiles (for the special case when

= 0,

Section: Validation Of Our Numerical Schemementioning

confidence: 89%

Vortex generation due to multiple localized magnetic fields in the hybrid nanofluid flow – A numerical investigation

Ahmad¹,

Ali²,

Katbar³

et al. 2023

Heliyon

Self Cite

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“…Heat transfer enhancement was noted in the cavity for hybrid nanoparticles. The flow within a square enclosure was taken by Yasmin et al [25] to analyze the heat transport and flow features of MHD Cassonna nanofluids. Further investigations on cavity flows can be found in [26][27][28].…”

Section: Introductionmentioning

confidence: 99%

Numerical Assessment of Dipole Interaction with the Single-Phase Nanofluid Flow in an Enclosure: A Pseudo-Transient Approach

Ayub

Ahmad

et al. 2022

Materials

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Nanofluids substantially enhance the physical and thermal characteristics of the base or conducting fluids specifically when interacting with the magnetic field. Several engineering processes like geothermal energy extraction, metal casting, nuclear reactor coolers, nuclear fusion, magnetohydrodynamics flow meters, petrochemicals, and pumps incorporate magnetic field interaction with the nanofluids. On the other hand, an enhancement in heat transfer due to nanofluids is essentially required in various thermal systems. The goal of this study is to figure out that how much a magnetic field affects nanofluid flow in an enclosure because of a dipole. The nanofluid is characterized using a single-phase model, and the governing partial differential equations are computed numerically. A Pseudo time based numerical algorithm is developed to numerically solve the problem. It can be deduced that the Reynolds number and the magnetic parameter have a low effect on the Nusselt number and skin friction. The Nusselt number rises near the dipole location because of an increase in the magnetic parameter Mn and the Reynolds number Re. The imposed magnetic field alters the region of high temperature nearby the dipole, while newly generated vortices rotate in alternate directions. Furthermore, nanoparticle volume fraction causes a slight change in the skin friction while it marginally reduces the Nusselt number.

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“…Almakki et al [26] assessed the magnetohydrodynamic micropolar-nanoliquid transport using an extending sheet. Yasmin et al [27] developed magnetohydrodynamic Casson nanoliquid transport using the Brinkman framework. Few studies on magnetohydrodynamics (MHD) with hybrid nanoliquids can be seen in [28][29][30][31][32][33][34].…”

Section: Introductionmentioning

confidence: 99%

Numerical Investigation for Radiative Transport in Magnetized Flow of Nanofluids due to Moving Surface

Waqas

Khan

Alghamdi

et al. 2021

Mathematical Problems in Engineering

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In this article, we examined the magnetized flow of ethylene glycol- 50 − 50 % water-based nanoliquids comprising molybdenum disulfide ( MoS 2 ) across a stretching sheet. Flow properties were examined under the impacts of magnetic field and thermal radiation. The behavior of heat generation/absorption is also accounted. Similarity transformations are used on the system of PDEs to get nondimensional ODEs. The obtained nondimensional ODEs are solved with the help of the Runge–Kutta–Fehlberg method via computational software MATHEMATICA. The behavior of prominent parameters for velocity and thermal profiles is plotted graphically and discussed in detail. It is depicted that the temperature field is upgraded with increase in the heat generation/absorption parameter. Furthermore, a larger Schmidt number causes reduction in the concentration field. The current formulated model may be useful in biomedical engineering, biotechnology, nanotechnology, biosensors, crystal growth, plastic industries, and mineral and cleaning oil manufacturing.

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MHD Casson nanofluid flow in a square enclosure with non-uniform heating using the Brinkman model

Cited by 13 publications

References 37 publications

Vortex generation due to multiple localized magnetic fields in the hybrid nanofluid flow – A numerical investigation

Vortex generation due to multiple localized magnetic fields in the hybrid nanofluid flow – A numerical investigation

Numerical Assessment of Dipole Interaction with the Single-Phase Nanofluid Flow in an Enclosure: A Pseudo-Transient Approach

Numerical Investigation for Radiative Transport in Magnetized Flow of Nanofluids due to Moving Surface

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