Analysis of second law on Eyring‐Powell nanoliquid flow in a vertical microchannel considering magnetic field and convective boundary

Sindhu, S.; Gireesha, B.J.

doi:10.1002/htj.21878

Cited by 10 publications

(6 citation statements)

References 45 publications

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“…Sindhu et al. [11] examined the flow of Eyring–Powell nanofluid in a vertical microchannel under the influence of a magnetic field with convective boundary conditions. Researchers such as Arabpour et al.…”

Section: Introductionmentioning

confidence: 99%

“…To bring about quadratic convection in dusty Casson and Carreau fluids, Mahanthesh et al [10] utilized a variety of physical phenomena, including convective heating, heat generation, and radiation. Sindhu et al [11] examined the flow of Eyring-Powell nanofluid in a vertical microchannel under the influence of a magnetic field with convective boundary conditions. Researchers such as Arabpour et al [12] and Choi et al [13] have discussed how fluid flow works in microchannels in this direction.…”

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confidence: 99%

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Effects of nonlinear thermal radiation on magnetized Al2O3${\rm Al}_2 {\rm O}_3$‐Blood${\rm Blood}$ nanofluid flow through an inclined microporous channel: An investigation of second law analysis

Ogunsola,

Oyedotun

2023

Electrophoresis

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This study aimed at studying the variational effect of nonlinear thermal radiation on the flow of Casson nanofluid () through a porous microchannel with entropy generation. The novelty of this investigation includes the incorporation of porous media, nonlinear radiative heat flux, and convective heat transfer at the channel interface into the energy equation, which results in an enhanced analysis for the cooling design and heat transfer of microdevices that utilize nanofluid flow. Particularly, alumina (Al2O3) is considered as the nanoparticles in this blood base fluid due to associated advanced pharmaceutical applications. With dimensionless variables being utilized, the governing equations are minimized to their simplest form. The Chebysev‐based collocation technique was employed to numerically solve the resultant ordinary differential equations with the associated boundary conditions and the impact of flow, thermal, and irreversibility distribution fields are determined through graphs. The findings identified that higher levels of Hartmann number produce the Lorentz force, which limits fluid flow and lowers velocity, the response of nonlinear thermal radiation diminishes the heat transfer rate, and a rise in the Casson parameter also reduces the Bejan number. The results of this research can be used to improve heat transfer performance in biomedical devices, design‐efficient energy conversion cycles, optimize cooling systems, and cover a wide range of energy technologies from renewable energy to aerospace propulsion.

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Section: Introductionmentioning

confidence: 99%

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confidence: 99%

Effects of nonlinear thermal radiation on magnetized Al2O3${\rm Al}_2 {\rm O}_3$‐Blood${\rm Blood}$ nanofluid flow through an inclined microporous channel: An investigation of second law analysis

Ogunsola,

Oyedotun

2023

Electrophoresis

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“…Li et al 33 analyzed entropy produced for the cavitating flow using the shear stress transport

k \mbox{-} \omega

turbulence model. Sindhu and Gireesha 34 investigated the second law on Eyring–Powell nanoliquid flowing within a vertically placed microchannel by modeling the equations using a magnetic field and convective boundary. Felicita et al 35 looked into the third‐grade fluid flowing in a microchannel and investigated the entropy formed during the flow.…”

Section: Introductionmentioning

confidence: 99%

Magnetohydrodynamic flow of a micropolar nanofluid in association with Brownian motion and thermophoresis: Irreversibility analysis

2022

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This investigation was carried out with the purpose of presenting the flow of micropolar fluid flowing in the microchannel placed parallel to the ground. The prime aim of the work was to study the behavior of micropolar fluid and the response of the microrotation component when the two significant mechanisms namely Brownian movement and thermophoresis are accounted for, as these effects are mainly concerned with the motion of the particles of nano‐dimensions. For the flow of micropolar, we account for the extra kinematics variables combined with the classical continuum mechanics namely microinertia moment tensor and gyration tensor. Magnetic effect and suction/injection of the fluid through the channel walls are also facilitated. The influence on the fluid concentration due to the presence of activation energy was accounted in the present examination. On considering all of these effects, equations are carefully modeled and the solution was attained with the aid of Runge–Kutta Fehlberg 4–5th order method using a shooting scheme. The results have deciphered that the presence of material parameter elevates the microrotation component on the upper half of the channel and depletes it at the lower half. The microinertia parameter shows the opposite behavior of the material parameter. Brownian motion parameter is found to enhance the thermal profile and concentration profile. Lesser entropy was generated when the material parameter was high.

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“…The dependence of fluid flow in a double-layered channel on slip boundary conditions has been observed by Abedin et al 30 Mohamed et al 31,32 examined the discrepancy of thermal energy and momentum of the different nanofluids with convective and slip boundary conditions. Gireesha et al 33,34 investigated the second law analysis of a nanofluid and Casson fluid flow in a microchannel in which convective boundary conditions have been considered.…”

Section: Introductionmentioning

confidence: 99%

Heat transfer and irreversibility rate in MHD flow of a hybrid nanofluid with Newton boundary condition, slip flow, and nonlinear thermal radiation

2021

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The magnetohydrodynamic flow of a water‐based Al 2 O 3 − normalCu hybrid nanoliquid through a vertical microchannel has been investigated in the presence of collective effects, such as volume fraction of nanoparticle, suction/injection, magnetic field, temperature‐dependent heat source, hydrodynamic slip, and convective boundary conditions. The current mathematical formulations have been worked out numerically by using the fourth‐ and fifth‐order Runge–Kutta–Fehlberg scheme. The physical aspects of variation in velocity, temperature, entropy generation, and Bejan number with considered governing parameters have been discussed via corresponding graphs. The obtained numerical results demonstrated that radiation parameter and nanoparticle volume fraction reduce the thermal energy of the hybrid nanofluid. Moreover, entropy generation diminishes with the Hartmann number and permeability parameter, whereas it enhances with the Grashof number and Biot number.

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Analysis of second law on Eyring‐Powell nanoliquid flow in a vertical microchannel considering magnetic field and convective boundary

Cited by 10 publications

References 45 publications

Effects of nonlinear thermal radiation on magnetized Al2O3${\rm Al}_2 {\rm O}_3$‐Blood${\rm Blood}$ nanofluid flow through an inclined microporous channel: An investigation of second law analysis

Effects of nonlinear thermal radiation on magnetized Al2O3${\rm Al}_2 {\rm O}_3$‐Blood${\rm Blood}$ nanofluid flow through an inclined microporous channel: An investigation of second law analysis

Magnetohydrodynamic flow of a micropolar nanofluid in association with Brownian motion and thermophoresis: Irreversibility analysis

Heat transfer and irreversibility rate in MHD flow of a hybrid nanofluid with Newton boundary condition, slip flow, and nonlinear thermal radiation

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