Simulation of Dissipative Hybrid Nanofluid (PEG-Water + ZrO2 + MgO) Flow by a Curved Shrinking Sheet with Thermal Radiation and Higher Order Chemical Reaction

The heat transmission capabilities of hybrid nanofluids are superior to those mono nanofluids. In addition solar collectors and military equipment, they may be found in a number areas including exchanger, automotive industry, transformer cooling electronic cooling. purpose this study was evaluate the significance higher order chemical reaction parameter on radiative flow nanofluid (polyethylene glycol (PEG)–water combination: base fluid zirconium dioxide, magnesium oxide: nanoparticles) via curved shrinking sheet with viscous dissipation. Flow-driven equations were transformed into nonlinear ODEs using appropriate similarity transmutations, then solved bvp4c solver (MATLAB built-in function). results two scenarios, PEG−Water+ZrO2+MgO (hybrid nanofluid) PEG−Water+ZrO2, (nanofluid) reported. draw important inferences about physical features, such as transfer rate, correlation coefficient used. main findings that curvature lowers velocity, Eckert increases temperature fluid. It observed volume fraction nanoparticles enhances skin friction lessens same. noticed when (K) takes input range 0.5≤K≤2.5, decreases at rate 1.46633 (i.e., 146.633%) (in case 1.11236 111.236%) per unit value parameter. Increasing rates 3.481179 348.1179%) 2.745679 nanoparticle (ϕ1) 0≤ϕ1≤0.2. detected that, (Eck) increases, Nusselt decreases. decrement 1.41148 141.148%) 1.15337 153.337%) 0≤Eck≤0.2. nanofluid, it discovered mass 1.497214 149.7214%) (Kr) 0≤Kr≤0.2. addition, we checked our against other researchers respectable degree agreement.