Sustainable thermal resources play a dynamic role in industrial and engineering growth and subsequently improve energy consumption. The attention of researchers toward renewable energy resource is subsequently improved with the interaction of various kinds of nanoparticles. This thermal contribution aims to explore the novel applications of nanoparticles with nonlinear radiative phenomena. The induced flow is subject to the stagnation point flow via curved stretched cylinder. Two famous base materials like ethylene glycol and water are considered which are significantly used in industrial and engineering phenomena as an energy source. The comparative thermal aspect for the suspension of and is focused. The thermal characteristics of nanoparticles and base materials are presented. The motivations for exploring the thermal impact of nanoparticles with ethylene glycol and water are justified applications in solar systems, energy production, engine oils, chemical reaction, and as a modified energy source. After altering the thermal flow problem into dimensionless form, the numerical computations were performed via Keller Box scheme. It is observed that the heat transfer rate is enhanced by increasing the solid volume fractions. The rate of thermal phenomenon controls due to the velocity ratio parameter.