This study investigates the result of magnetic induction on Ethylene Glycol-water (EG-water) based tangent hyperbolic cross nanoliquid flow above a porous stretched region in the existence of thermic energy. Due to effective thermal conductivity, we considered Zirconium dioxide (ZrO2) and Graphene oxide (GO) nanoparticles and embedded them in the EG-water combination (50%–50%). A theoretical model was established and resolved numerically using the Keller-Box approach. The outcomes are executed in the existence and absence of magnetic induction and exemplified graphically to understand the behavior of flow and thermal areas. The magnetic induction Prandtl number inclines to enlarge the heat diffusion rate of hyperbolic-tangent cross nano liquid in the occurrence of the magnetic induction. The heat transmission rate of tangent hyperbolic hybrid nanofluids is high in the existence of magnetic induction when related to its absence. Weissenberg numbers and permeability are controlling factors for wall friction. The electromagnetic field assists in regulating the thermal and momentum fields.