Two-Phase Numerical Simulation for the Heat and Mass Transfer Evaluation Across a Vertical Deformable Sheet with Significant Impact of Solar Radiation and Heat Source/Sink

Obalalu, A. M.; Oni, M. O.; Khan, Umair; Abbas, Amir; Muhammad, Taseer; Zaib, Aurang

doi:10.1007/s13369-023-08585-z

Cited by 16 publications

(2 citation statements)

References 45 publications

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“…The following equations are derived based on the aforementioned assumptions (Alshuhail et al ., 2023; Obalalu et al ., 2023b):…”

Section: Mathematical Modelingmentioning

confidence: 99%

“…Sadiq and Hayat (Alshuhail et al, 2023) discussed Maxwell D-F flow in permeable medium Darcy Forchheimer accompanied with convectively warmed sheet. Obalalu et al, (2023b) made a comprehensive study of third grade magnetohydrodynamic fluid flow with darcy Forchheimer law and heat transfer over a stretching sheet. Hayat et al (Ph, 1901) studied D-F nanofluid flow for the analysis of entropy generation minimization over a curved stretching sheet with partial slip influenced.…”

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confidence: 99%

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Heat transfer analysis of thermal radiative over a stretching curved surface using molybdenum disulfide and silicon dioxide composite material under the influence of solar radiation

Obalalu,

Darvesh,

Aselebe

et al. 2024

MMMS

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PurposeThe primary focus of this study is to tackle a critical industry issue concerning energy inefficiency. This is achieved through an investigation into enhancing heat transfer in solar radiation phenomena on a curved surface. The problem formulation of governing equations includes the combined effects of thermal relaxation, Newtonian heating, radiation mechanism, and Darcy-Forchheimer to enhance the uniqueness of the model. This research employs the Cattaneo–Christov heat theory model to investigate the thermal flux via utilizing the above-mentioned phenomenon with a purpose of advancing thermal technology. A mixture of silicon dioxide (SiO_2)\ and Molybdenum disulfide (MoS_2) is considered for the nanoparticle’s thermal propagation in base solvent propylene glycol. The simulation of the modeled equations is solved using the Shifted Legendre collocation scheme (SLCS). The findings show that, the solar radiation effects boosted the heating performance of the hybrid nanofluid. Furthermore, the heat transmission progress increases against the curvature and thermal relaxation parameter.Design/methodology/approachShifted Legendre collocation scheme (SLCS) is utilized to solve the simulation of the modeled equations.FindingsThe findings show that, the solar radiation effects boosted the heating performance of the hybrid nanofluid. The heat transmission progress increase against the curvature and thermal relaxation parameter.Originality/valueThis research employs the Cattaneo–Christov heat theory model to investigate the thermal flux via utilizing the above-mentioned phenomenon with a purpose of advancing thermal technology.

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“…The following equations are derived based on the aforementioned assumptions (Alshuhail et al ., 2023; Obalalu et al ., 2023b):…”

Section: Mathematical Modelingmentioning

confidence: 99%

mentioning

confidence: 99%

Heat transfer analysis of thermal radiative over a stretching curved surface using molybdenum disulfide and silicon dioxide composite material under the influence of solar radiation

Obalalu,

Darvesh,

Aselebe

et al. 2024

MMMS

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Bidirectional Stabilized Non‐Newtonian Fluid Flow With Prescribed Heat Mechanism and Thermal Radiation in Stretching Sheet

M.,

Koti

2024

Heat Trans

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This study investigates the behavior of non‐Newtonian fluid flow under magnetohydrodynamic (MHD) conditions, focusing on heat radiation effects during viscous flow over an elongated surface with penetrable boundaries. This research is important due to the increasing applications of non‐Newtonian fluids in manufacturing and technical fields, necessitating advanced modeling techniques to accurately simulate their behavior under MHD conditions. To address the limitations of previous analyses that inadequately accounted for electrical field effects, we propose the Impetus Proliferate Method to enhance fluid flow velocity and establish better control over heat dissipation in practical devices like phase change thermal systems and power heat flux systems. The study employs the Novel Perpetuate Reconciliation Approach to manage heat transfer effectively within the elongated medium, revealing that heat transfer decreases as boundary layer thickness over the porous medium increases. Additionally, the Cogency Fortification Method significantly enhances the stability of non‐Newtonian fluid flow over the extended sheet. The implementation of these methodologies in MATLAB Simulink provides a robust simulation framework, offering novel insights into the dynamic behavior of non‐Newtonian fluids in MHD contexts and improving upon existing modeling techniques by integrating electrical field effects and deepening the understanding of heat transfer phenomena. Finally, the proposed model's accuracy is said to be 95%.

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Computational Analysis to Explore Bioconvective Williamson Nanofluid Non-Darcian Flow over a Convective Cylindrical Surface with Gyrotactic Microorganisms and Activation Energy Aspects

Bilal,

Asadullah,

Malik

2024

BioNanoSci.

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Two-Phase Numerical Simulation for the Heat and Mass Transfer Evaluation Across a Vertical Deformable Sheet with Significant Impact of Solar Radiation and Heat Source/Sink

Cited by 16 publications

References 45 publications

Heat transfer analysis of thermal radiative over a stretching curved surface using molybdenum disulfide and silicon dioxide composite material under the influence of solar radiation

Heat transfer analysis of thermal radiative over a stretching curved surface using molybdenum disulfide and silicon dioxide composite material under the influence of solar radiation

Bidirectional Stabilized Non‐Newtonian Fluid Flow With Prescribed Heat Mechanism and Thermal Radiation in Stretching Sheet

Computational Analysis to Explore Bioconvective Williamson Nanofluid Non-Darcian Flow over a Convective Cylindrical Surface with Gyrotactic Microorganisms and Activation Energy Aspects

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