Impact of cubic autocatalysis and infinite shear rate characteristics in MHD Carreau fluid over radiated bi-directional sheet; ANN-based computational scheme
Adil Darvesh, Luis Jaime Collantes Santisteban, Fethi Mohamed Maiz, Manuel Sánchez‐Chero, Hamiden Abd El-Wahed Khalifa, William Rolando Miranda Zamora, Hakim AL Garalleh, Carlos William Atalaya Urrutia
Abstract
• Thermal transport analysis in Non-Newtonian Carreau fluid over a bi-directional radiated stretching sheet. • Implementation of Carreau model to featuring non-Newtonian characteristics. • Incorporation of MHD and cubic autocatalysis in the physical model. • Development of a hybrid computational framework that incorporates bvp4c and (LM-ANN) scheme. • Effectiveness of emerging parameters on velocity and temperature via MATLAB illustrations statistical data. The implementation of advanced computational strategies for thermal transport analysis in fluid flow processes plays a significant role, which is crucial in modern thermal management systems. Artificial neural network (ANN) computational procedures play a vital role in solving the stiff nonlinear mathematical models due to their strong capability to train and predict data efficiently. The present endeavor delves into the discussion of heat transfer mechanism in Carreau fluid over a bi-directional stretching sheet, featuring magnetohydrodynamics (MHD), infinite shear rate characteristics and exhibiting cubic autocatalysis effect. In addition, magnetic effects are added to analyze the heat transfer efficiency and dual chemical reactions aid in convenient assessment of fluid concentration. Physical models generated partial differential equations (PDEs) are shifted into ordinary differential equations (ODEs) via introducing similarity variables. Computational analysis is made by employing a joint computational procedure i.e., bvp4c and Levenberg Marquardt neural network scheme (LM-NN). The results are displayed by different MATLAB illustrations and statistical data. The concentration field of Carreau fluid increased due to augmentation in diffusion parameter for both pseudoplasticity and dilatant region. Velocity profile intensified in both axial directions due to numeric growth in values of Weissenberg number and infinite shear rate parameter Uniform chemical reaction illustrates the motion of nanoparticles in the liquid, causing an increase in temperature during shear thinning and shear thickening due to the immersion of these particles in the base fluid.