Hybrid Advances, Journal Year: 2025, Volume and Issue: unknown, P. 100446 - 100446
Published: March 1, 2025
Language: Английский
Neural Computing and Applications, Journal Year: 2021, Volume and Issue: 33(22), P. 15719 - 15729
Published: June 12, 2021
Language: Английский
Citations
32
Heliyon, Journal Year: 2022, Volume and Issue: 8(12), P. e11854 - e11854
Published: Nov. 29, 2022
The heat and mass relocation properties of magneto-hydrodynamic mixed convective viscoelastic hybrid nanofluid flow induced by an extending spinning disk under the effect entropy generation, thermal radiation, condition, velocity, concentration slips has been investigated in this study. For nanofluid, amalgamation aluminum nitride alumina nanoparticles embedded carboxymethyl cellulose with a volume 0.0%-0.4% is considered for acquired system partial differential equations from intended problem translated into ordinary employing resemblance conversion solved Galerkin finite element approach. main effects governing constraints on velocity field, temperature dispersion, concentration, Bejan number, production, skin friction, Nusselt Sherwood number were detailed depicted graphs tables. results show that snowballing constraint fraction solid non-sized particles Al2O3 AlN can be used to control fluid speed. Also, it observed result increment magnetic field parameter causes decline field. However, increase upsurge distribution. Entropy generation also regulated using higher nanoparticles. This numerical theoretical investigation more useful bio-viscoelastic fluids, advanced technology, industry.
Language: Английский
Citations
22
Magnetochemistry, Journal Year: 2022, Volume and Issue: 8(12), P. 188 - 188
Published: Dec. 14, 2022
The utilization of hybrid nanofluids (HNs) to boost heat transfer is a promising area study, and thus, numerous scientists, researchers, academics have voiced their admiration interest in this area. One the main functions dynamic role cooling small electrical devices such as microchips associated gadgets. major goal study perform an analysis buoyancy flow shrinking/stretching sheet, whilst considering fascinating practical uses nanofluids. influence nonlinear source/sink induced by micropolar fluid also inspected. Water-based alumina copper nanoparticles are utilized calculate fine points features transfer. governing equations framed with acceptable assumptions required similarity transformations used turn set partial differential into ordinary equations. bvp4c technique solve simplified Dual solutions presented for certain values stretching/shrinking parameters well mixed convective parameter. In addition, shear stress coefficient first-branch solution (FBS) escalates decelerates second-branch (SBS) superior impact magnetic parameter, mass transpiration solid volume fraction, while contrary behavior seen both (FB SB) larger material
Language: Английский
Citations
20
Scientific Reports, Journal Year: 2021, Volume and Issue: 11(1)
Published: Nov. 17, 2021
Abstract This article focuses on hybrid nanofluid flow induced by stretched surface. The present context covers stagnation point of a with the effect heat generation/absorption. Currently most famous class nanofluids is Hybrid nanofluid. It contains polystyrene and titanium oxide as nanoparticles water base fluid. First time attributes transfer are evaluated utilizing polystyrene–TiO 2 /H O Partial differential equations converted into ordinary equation using appropriate transformations for velocity. Homotopy analysis method operated solution equations. Flow disclosed graphically unlike parameters. Resistive force rate deliberated mathematically graphically. deduced that velocity field enhanced ratio parameter whereas temperature grows generation/absorption coefficient. To judge production any engineering system entropy generation also calculated. noticed Prandtl number Eckert while it shows opposite behavior difference parameter.
Language: Английский
Citations
26
Hybrid Advances, Journal Year: 2025, Volume and Issue: unknown, P. 100446 - 100446
Published: March 1, 2025
Language: Английский
Citations
0