Abstract
Thermal radiations and effective characteristics of the nanoparticles play a vibrant role in the heat transfer enhancement. This work aims to investigate the influence of thermophysical characteristics of nano-diamond (ND) and silver (Ag) nanoparticles on the heat transfer intensifications in the nonlinear radiative and dissipative flow over an arched geometry. A self-similar coupled nature of the nanofluid model is acquired via similarity transformations. Furthermore, the mathematical treatment of the model is carried out by the RK scheme. Moreover, stimuli of various pertinent flow parameters on the velocity, heat transfer, streamlines, and isotherms are examined graphically.
Highlights
Flow over stretching surface acquired considerable interest of the researchers and engineers owing to its versatile applications in engineering and industrial zone
GRAPHICAL RESULTS AND DISCUSSION The self-similar flow parameters playing fascinating role in the flow characteristics over the domain of interest and graphical depiction is of huge significance which illustrates fluctuations in the flow characteristics for varying parameters
These alterations are discussed for velocity, thermal distribution and thermophysical characteristics
Summary
Flow over stretching surface acquired considerable interest of the researchers and engineers owing to its versatile applications in engineering and industrial zone. Analysis of the flow characteristics over stretching arched geometry cannot be disregarded. Analysis of heat transfer acquired considerable attention of the researchers, scientists and engineers owing its versatile uses in industries as well as engineering side. It is a renowned fact that thermal enhancement in conventional liquids is not up to the mark for production of various products in industries and technological purposes. The utilization of carrier liquids is not fruitful for those purposes which needed a particular amount of heat and caused so many issues to accomplishment of such purposes. To acquired considerable thermal characteristics for the productions, an innovative class of liquids is needed to accomplish favorable heat transfer and overcome
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