The hybrid nanofluids are effective in terms of cooling where the range of temperature is high and includes a significant range of thermal applications, such as cooling electrical equipment, heat exchangers, automotive industry, heat pipes, manufacturing industry, and solar energy. As a result of these facts, this particular research emphasizes on the silver- titanium oxide /water hybrid nanofuid flow through an exponentially stretching sheet. The impacts such as viscous dissipation, magneto hydrodynamics, porosity, thermal radiation and heat generation have been also taken into account. By utilizing non-dimensional quantities and similarity functions, the flow model is transformed and simplified to a system of ordinary differential equations. With the help of the numerical method Runge-Kutta with shooting technique in Matlab script, the desired system is solved. It has been discovered that stronger the porosity parameter raises the temperature while diminishing the velocity. It additionally emphasizes that augmentations in the magnetic parameter, Eckert number, radiation parameter, and volume percentage of T i O 2 and A g nanoparticles proportional to the temperature profile. The results demonstrate satisfactory congruence’s when compared to the current literature.