Your search keyword '"Taleb, Mustapha"' showing total 5 results

1. Exploratory evaluation supported by experimental and modeling approaches of Inula viscosa root extract as a potent corrosion inhibitor for mild steel in a 1 M HCl solution

Author

Adil Mahraz Mohamed, Salim Rajae, Loukili El Hassania, Assouguem Amine, Kara Mohammed, Ullah Riaz, Bari Ahmed, Fidan Hafize, Laftouhi Abdelouahid, Mounadi Idrissi Amine, Hammouti Belkheir, Rais Zakia, and Taleb Mustapha

Subjects

inula viscosa, hplc, corrosion inhibitor, dft, electrochemical impedance spectroscopy, Biology (General), QH301-705.5

Abstract

The corrosion of metals poses a threat to the economy, the environment, and human health due to undesirable reactions and contaminated products. Corrosion inhibitors, including natural products, can play a key role in protecting metallic materials, especially under challenging conditions. In this study, the roots of the Inula viscosa plant were examined for their ability to act as corrosion inhibitors in a 1 M hydrochloric acid (HCl) solution. Different extracts of the plant were evaluated for their corrosion inhibition capacity in a 1 M HCl solution. The effectiveness of different plant extracts was assessed, including an aqueous extract, an ethanolic extract, and a combined water–ethanol extract. Compounds present in the roots of Inula viscosa were identified using high-performance liquid chromatography. The electrochemical properties of the extracts were studied using various techniques such as open circuit potential, electrochemical impedance spectroscopy, and potentiodynamic polarization. Additionally, surface analysis after immersion was performed using scanning electron microscopy. Electrochemical data revealed that Inula viscosa root (IVR) extracts acted as mixed-type corrosion inhibitors with pronounced cathodic characteristics. The inhibitory efficiency was closely related to the concentration of Inula viscosa (I. viscosa), showing a significant increase with higher concentrations. This resulted in a decrease in corrosion current and an increase in polarization resistance. Notably, inhibitory efficiency reached high levels, up to 97.7% in mixed extract which represents a mixture between water and ethanol. In our study, it was observed that the mixed extract (water + ethanol) allowed for a greater corrosion inhibition compared to the other solvents studied, 97.7%. Surface analyses confirmed the formation of an organic film layer on the steel surface, attributed to the bonding of functional groups and heteroatoms in I. viscosa components. Therefore, this study paves the way for the potential integration of I. viscosa as a promising corrosion inhibition material, offering durable protection against steel corrosion and opening avenues for various related applications.

Published

2024

2. An Intelligent and Efficient Synthesis of New Inhibitors against Corrosion of Mild Steel in Acidic Media

Author

Nadia Arrousse, Nahlé, Ayssar, Mabrouk, El Houssine, Salim, Rajae, El hajjaji, Fadoua, Rais, Zakia, and Taleb, Mustapha

Published

2021

3. Essential oil of “Foeniculum vulgare”: antioxidant and corrosion inhibitor on mild steel immersed in hydrochloric medium

Author

Bouoidina, Asmae, Chaouch, Mehdi, Abdellaoui, Abdelfattah, Lahkimi, Amal, Hammouti, Belkheir, El-Hajjaji, Fadoua, Taleb, Mustapha, and Nahle, Ayssar

Published

2017

4. Towards Understanding the Anticorrosive Mechanism of Novel Surfactant Based on Mentha pulegium Oil as Eco-friendly Bio-source of Mild Steel in Acid Medium: a Combined DFT and Molecular Dynamics Investigation

Author

Taleb Mustapha, Obot Ime Bassey, El-Hajjaji Fadoua, Hammouti Belkheir, Abdellaoui Abdelfattah, Emran Khadijanh, Belghiti Mohammed Elalaoui, Elmelouky Abderrahmane, and Bouoidina Asmae

Subjects

Chemistry, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, law.invention, Corrosion, Corrosion inhibitor, chemistry.chemical_compound, law, Molecule, Gravimetric analysis, Mentha pulegium, Gas chromatography, 0210 nano-technology, Menthol, Essential oil, Nuclear chemistry

Abstract

Today, due to the increasingly stringent European directives concerning the use of molecules with certain toxicities towards the environment or their users, the essential oils, extracts, and molecules derived from plants exhibiting the characteristic of being biodegradable can be considered as a source of green corrosion inhibitors instead of harmful synthetic chemicals. The present work was devoted to testing the essential oil extracted from Mentha pulegium leaves(M1) as a corrosion inhibitor for C-steel in 1 mol/L HCl solution using both electrochemical techniques and gravimetric measurements for the evaluation of the inhibition efficiencies at different temperatures. The results obtained showed that the inhibition efficiency increased with an increase in M1 concentration to reach a maximum value of 92.21%. We sought to determine the molecule responsible for this high efficiency, starting with the analysis of oil chemical composition by gas chromatography coupled with mass spectrometry. This analysis revealed that menthol(M2) and isomenthol(M3) were the principal constituents. In order to identify the molecule responsible for the inhibition and explain the protection mechanism involved, quantum chemical calculations and Monte Carlo simulations were used to explain the interaction of menthol, the major constituent of M1 with the Fe-surface. To practically confirm these results, we studied the action of 1 mol/L HCl on steel with and without the addition of M2 by both methods(gravimetric and electrochemical study). A very high efficiency was obtained, an efficiency of 94.90% at 10‒3 mol/L, which was retained for a long exposure time, and slightly decreased in function of temperature. Finally, a good correlation between the experimental data, theoretical calculations, and SEM studies was obtained, which denied that the M1 efficiency was only a result of a synergy effect and confirmed the high efficiency of Mentha oil and its main component(menthol) as a strong ecological inhibitor of corrosion.

Published

2019

5. Corrosion protection studies of different alloys in 1 M HCl by benzimidazole derivative: Combined molecular dynamic simulations/DFT.

Author

Arrousse, Nadia, Fernine, Yasmine, Haldhar, Rajesh, Berdimurodov, Elyor, Ichou, Hamza, Al-Zaqri, Nabil, Koudad, Mohammed, Kim, Seong-Cheol, and Taleb, Mustapha

Subjects

CORROSION & anti-corrosives, COPPER corrosion, BENZIMIDAZOLE derivatives, DYNAMIC simulation, COPPER, METAL coating, COPPER surfaces, MILD steel, QUANTUM chemistry

Abstract

Corrosion prevention of metals like Steel, Aluminum, and Copper is an interesting problem in industries, to solve this problem corrosion inhibitors are one of the most effective applications for metal protection against corrosion in aggressive media. The effect of (2 E)-3-(6-phenylimidazo[2,1- b ][1,3]thiazol-5-yl)-1-(2,4,6-trimethylphenyl)prop-2-en- 1-one (KO38) on the protection of steel, aluminum, and copper in 1 M HCl medium was examined using electrochemical polarization tests to assess inhibition efficiency, also scanning electron microscopy (SEM) to analyze the surface of metals. The maximum protection capacity of KO38 by the method of polarization is between 96% and 97% for the three metals exposed in an acid solution containing 10−4 M. The organic inhibitors can be classified as mixed-type inhibitors since they inhibited both anodic corrosion and cathodic corrosion. The study of the dynamic simulation (DM) helped to visualize the energies of adsorption of the molecule (KO38) on the interfaces of Iron (110), Aluminum (111), and Copper (111), the calculations of quantum chemistry were analyzed by (DFT) at B-3LYP /6–311 G (d, p). The experimental results are in good agreement with the theoretical studies. • One novel organic benzimidazole derivative has been investigated for its anti-corrosive activities. • KO38 show between 96% and 97% corrosion inhibition efficiency at 10−4 M concentrations. • The morphological studies suggest its extraordinary surface adsorption abilities. • The theoretical investigations also support the experimental outcomes. [ABSTRACT FROM AUTHOR]

Published

2023