 The current study investigated the numerical simulation of nano-liquid boundary layer flow with gerotactic microbes. The effects of chemical reaction, heat generation absorption, buoyancy force, and Arrhenius activation energy were taken into account. The flow was modeled using a system of non-linear partial differential equations which were then transformed to a set of ordinary differential equations for numerical computation. The results showed that the velocity profile decreased with increasing inclination angle and Richardson number, while it increased with increasing curvature factor. Additionally, the energy field increased with increasing inclination angle and heat source term, while it decreased with increasing Prandtl number and Richardson number. This article was authored by Hakeem A. Hoffman, Bilal Ali, Sidra Jubair, and others.