A qualitative analysis of the artificial neural network model and numerical solution for the nanofluid flow through an exponentially stretched surface

Asad Ullah; Asad Ullah; Hongxing Yao; Waseem; Abdus Saboor; Fuad A. Awwad; Emad A. A. Ismail

doi:10.3389/fphy.2024.1408933

Frontiers in Physics (Sep 2024)

A qualitative analysis of the artificial neural network model and numerical solution for the nanofluid flow through an exponentially stretched surface

Asad Ullah,
Asad Ullah,
Hongxing Yao,
Waseem,
Abdus Saboor,
Fuad A. Awwad,
Emad A. A. Ismail

Affiliations

Asad Ullah: School of Finance and Economics, Jiangsu University, Zhenjiang, Jiangsu, China
Asad Ullah: Department of Mathematical Sciences, University of Lakki Marwat, Lakki Marwat, Pakistan
Hongxing Yao: School of Finance and Economics, Jiangsu University, Zhenjiang, Jiangsu, China
Waseem: School of Mechanical Engineering, Jiangsu University, Zhenjiang, Jiangsu, China
Abdus Saboor: Institute of Numerical Sciences, Kohat University of Science and Technology (KUST), Kohat, Pakistan
Fuad A. Awwad: Department of Quantitative Analysis, College of Business Administration, King Saud University, Riyadh, Saudi Arabia
Emad A. A. Ismail: Department of Quantitative Analysis, College of Business Administration, King Saud University, Riyadh, Saudi Arabia

DOI: https://doi.org/10.3389/fphy.2024.1408933
Journal volume & issue: Vol. 12

Abstract

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This article aims to analyze the two-dimensional (2D) nanofluid (Ag/C2H6O2) flow past an exponentially stretched sheet. The magnetic field impact, heat source/sink, and convection in the thermal profile are taken into account. The complexity of the problem is reduced by introducing a dimensionless group of functions. The reduced model is transformed into a system of first-order ordinary differential equations (ODEs). This system is further analyzed with the artificial neural network (ANN), which is trained using the Levenberg–Marquardt algorithm. The whole dataset is sub divided into three parts: training (70%), validation (15%), and testing (15%). The impact of nonlinear heat source/sink parameter, magnetic parameter, volume fraction of nanoparticles, and Prandtl number is displayed through graphs. The heat source, volume fraction, and the Prandtl number cause an increase in the thermal profile with its larger values. The magnetic parameter causes a decline in both the thermal and momentum boundary layers with its higher values. The analysis shows that the thermal energy profile is enhanced with the larger values of the volume fraction of silver nanoparticles and heat source. For each case study, the residual error (RE), regression line, and validation of the results are presented. The performance of the proposed methodology is numerically tabulated for the nanoparticle volume fraction shown in Table 3, where the minimum absolute error (AE) is 5.3373e−11 at ϕ=0.05. Based on this, we recommend ϕ=0.05 for better performance. The AEs for the ANN and bvp4c are computed for the state variables in Tables for the magnetic parameter M=5,10, and 15. These tables show the overall performance of the ANN and further validate the present study. We have also validated the results of the ANN through the mean squared error graphically, where the accuracy of the proposed methodology is proven.

Published in Frontiers in Physics

ISSN: 2296-424X (Online)
Publisher: Frontiers Media S.A.
Country of publisher: Switzerland
LCC subjects: Science: Physics
Website: https://www.frontiersin.org/journals/physics

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