Towards estimating the thermal properties of carbon allotropes and their derivatives: Hybridization between the artificial neural network method and the experimental design approach

A. Tarbi; T. Chtouki; A. Bouich; M.A. Sellam; Y. El kouari; H. Erguig; A. Migalska–Zalas

Results in Chemistry (Jan 2024)

Towards estimating the thermal properties of carbon allotropes and their derivatives: Hybridization between the artificial neural network method and the experimental design approach

A. Tarbi,
T. Chtouki,
A. Bouich,
M.A. Sellam,
Y. El kouari,
H. Erguig,
A. Migalska–Zalas

Affiliations

A. Tarbi: Superior School of Technology, Materials Physics and Subatomic Laboratory, Ibn-Tofail University, PB 242, 14000 Kenitra, Morocco; Corresponding author.
T. Chtouki: Superior School of Technology, Materials Physics and Subatomic Laboratory, Ibn-Tofail University, PB 242, 14000 Kenitra, Morocco
A. Bouich: Institut de Disseny i Fabricació, Universitat Politècnica, València, Spain
M.A. Sellam: Laboratory of Condensed Matter and Renewable Energy, Faculty of Sciences and Technology, University Hassan II of Casablanca, BP146, Mohammedia, Morocco
Y. El kouari: Laboratory of Condensed Matter and Renewable Energy, Faculty of Sciences and Technology, University Hassan II of Casablanca, BP146, Mohammedia, Morocco
H. Erguig: Superior School of Technology, Materials Physics and Subatomic Laboratory, Ibn-Tofail University, PB 242, 14000 Kenitra, Morocco
A. Migalska–Zalas: Faculty of Science and Technology, Jan Dlugosz University in Czestochowa, Al. Armii Krajowej 13/15, 42201 Czestochowa, Poland

Journal volume & issue: Vol. 7
p. 101295

Abstract

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Carbon allotropes and their derivatives have attracted the interest of many researchers owing to their ability to conduct heat. In this study, a multi-layer perception network (MLP) was developed to predict its thermal transport properties. Usually, trial and error are the appropriate solutions to find the number of hidden layers, the number of neurons, the activation, and the transfer function. To overcome this problem, we used the Surface Response Methodology (RSM), which identifies the influence of each parameter on the response and ends up finding a robust model of Artificial Neural Networks (ANN). The study demonstrated that hybridization between (ANN) and (RSM) methods is an efficient and powerful method for modeling the thermal conductivity of carbon allotropes; it allows to shorten the time to test different combinations. Notably, the study achieved exceptional results with a correlation coefficient surpassing 99.89%, a coefficient of determination exceeding 99.78%, and minimal RMSE (Root Mean Square Error).

Published in Results in Chemistry

ISSN: 2211-7156 (Online)
Publisher: Elsevier
Country of publisher: Netherlands
LCC subjects: Science: Chemistry
Website: https://www.journals.elsevier.com/results-in-chemistry/

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