Numerical exploration of tangent hyperbolic nanofluid flow subject to homogeneous and heterogeneous chemical reactions past a permeable wedge

Numerically, the effect of melting heat transfer on the magnetohydrodynamics (MHD) tangent hyperbolic nanofluid (Thnf) flow across a porous wedge is evaluated. Electronic devices generate a lot of heat while running, so Thnf is commonly used to reduce its temperature. Thnf has the ability to transfer heat more effectively, thus minimizing the risk of high temperature and component disruptions. The impact of heat source/sink, thermal radiation, and homogeneous/heterogeneous chemical reactions is also observed in the fluid flow. The modeled equations are reformulated into the non-dimensional form of ordinary differential equations (ODEs), which are further numerically solved through the nonlinear dynamics (ND)-solve approach. For the validity of the results, the numerical outcomes are relatively related to the published studies, which reveal that the proposed model and results are accurate and consistent. Furthermore, it can be determined from the graphical results that the fluid velocity drops with the rising effect of the permeability parameter whereas enhances with the positive variation in the power law index. The increasing influence of wedge angle and melting heat parameters augments the energy distribution rate. The intensifying impact of heterogeneous and homogeneous reaction parameters decreases the fluid concentration profile.