Thermal investigation of water-based radiative magnetized micropolar hybrid nanofluid flow subject to impacts of the Cattaneo-Christov flux model on a variable porous stretching sheet with a machine learning approach

This work investigates water-based micropolar hybrid nanofluid (MHNF) flow on an elongating variable porous sheet. Nanoparticles of diamond and copper have been used in the water to boost its thermal conductivity. The motion of the fluid is taken as two-dimensional with the impact of a magnetic field in the normal direction. The variable, permeable, and stretching nature of sheet’s surface sets the fluid into motion. Thermal and mass diffusions are controlled through the use of the Cattaneo-Christov flux model. A dataset is generated using MATLAB bvp4c package solver and employed to train an artificial neural network (ANN) based on the Levenberg-Marquardt back-propagation (LMBP) algorithm. It has been observed as an outcome of this study that the modeled problem achieves peak performance at epochs 637, 112, 4848, and 344 using ANN-LMBP. The linear velocity of the fluid weakens with progression in variable porous and magnetic factors. With an augmentation in magnetic factor, the micro-rotational velocity profiles are augmented on the domain 0 ≤ η < 1.5 due to the support of micro-rotations by Lorentz forces close to the sheet’s surface, while they are suppressed on the domain 1.5 ≤ η < 6.0 due to opposing micro-rotations away from the sheet’s surface. Thermal distributions are augmented with an upsurge in thermophoresis, Brownian motion, magnetic, and radiation factors, while they are suppressed with an upsurge in thermal relaxation parameter. Concentration profiles increase with an expansion in thermophoresis factor and are suppressed with an intensification of Brownian motion factor and solute relaxation factor. The absolute errors (AEs) are evaluated for all the four scenarios that fall within the range 10⁻³-10⁻⁸ and are associated with the corresponding ANN configuration that demonstrates a fine degree of accuracy.