In modern years, the conversion on solar radiation toward thermal energy had taken the important consideration by the appeal about sustainable power and heat raises. Nanofluid could show the significant role on developing the behavior on solar-thermal systems when that our capabilities about heat transfer improvement. That article analyzed numerically the flow on the hybrid nanofluid over the microchannel in existence of nonlinear solar radiation about different solar-thermal appliance. Effect of exponential heat source or sink and convective boundary condition are the focal concern of this study. The flow form was transferred with non-dimensionless model by convenient transformation, this numerical outcomes on nonlinear complex equations was formed to applying bvp4c technique. Subsequently, to influences on applicable parameters by the heat transfer of fluid had being revealed through the favor into tabular and graphical access. Outcomes communicate this solar radiation faster heat transport into division. The hybrid solution show massive increasing on heat transport 44.59% about division. Temperature decreased in the microchannel due to Biot number. The imitation outcomes are approved from the past issued work.
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