Purpose
The purpose of this paper is to discuss the flow and heat transference of unsteady nanofluid thin film flow due to linear stretching velocity over a horizontally placed stretching sheet in corporation of aligned magnetic field and non-uniform heat source/sink.
Design/methodology/approach
Leading equations of the course have been normalized via similarity approach and unraveled the resulting non-linear equations numerically by consuming RK-4 shooting practice to execute flow analysis.
Findings
A close agreement of two sets (for two different base fluids – polyvinyl alcohol and water) of result is perceived. The authors find that inclined magnetic field and nanoparticles concentration curbed velocity distribution which, in turn, causes enrichment of system of temperature distribution.
Originality/value
The paper acquires realistic numerical explanations in form of rapidly convergent series. The influence of emergent flow parameters on specific flow are made appropriately via graphs and charts. An unbiased result scrutiny of the existing section with formerly conveyed result is provided.
The present article explores steady, incompressible, and electrically conducting viscous hybrid-nanofluid flow through an impermeable slender stretching sheet. We have opted for water (H 2 O) as base fluid and two nanoparticles namely Al 2 O 3 and graphene for the hybrid-nanofluid. The consequence of nonuniform magnetic field and Hall current is accounted for in the flow distribution. Zero mass-flux boundary conditions have been included here. The leading partial differential equations of the acknowledged model revise to similarity variables. Next, the subsequent equations are numerically solved by a shooting scheme based on Runge-Kutta fourth-order procedure. The consequences of boosting flow factors on transport systems are achieved accurately through the requisite figures and charts. Concentration outlines are dual in nature when the wall-thickness factor intensifies. The rate of heat and mass transmit augments with wall-thickness factor.
This paper explores stagnation-point flow mechanism and the convective heat transmission of an incompressible viscous fluid encouraged by impermeable stretching sheet. Water
and the ethylene glycol
driven nanofluids comprising titanium oxide
nanoparticles in company of non-uniform heat source/sink accounted here. Effect of second order velocity slip and induced magnetic-field accounted in the presumed model. Primary equations of adopted model have been standardized through similarity methodology and resolved the subsequent equations numerically by expending RK-4 shooting exercise. The stimulus of encouraging flow parameters on the flow specific is made accurately through diagrams and charts. We measure the strength besides trend of the relation amongst the numerous emergent flow parameters with Skin friction coefficient, Nusselt number by using correlation co-efficient and the impression of the relation confirmed by employing Ficher’s
test. Here dual characteristic of induced magnetic-field has been witnessed for magnetic Prandtl number.
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