Your search keyword '"Taha, Mohd Faisal"' showing total 4 results

1. Synthesis and Characterization of Novel Thiosalicylate-based Solid-Supported Ionic Liquid for Removal of Pb(II) Ions from Aqueous Solution.

Author

Kamaruddin NAL, Taha MF, and Wilfred CD

Subjects

Lead, Silica Gel chemistry, Adsorption, Water, Ions chemistry, Kinetics, Ionic Liquids chemistry, Water Pollutants, Chemical chemistry

Abstract

The main objectives of this study are to synthesize a new solid-supported ionic liquid (SSIL) that has a covalent bond between the solid support, i.e., activated silica gel, with thiosalicylate-based ionic liquid and to evaluate the performance of this new SSIL as an extractant, labelled as Si-TS-SSIL, and to remove Pb(II) ions from an aqueous solution. In this study, 1-methyl-3-(3-trimethoxysilylpropyl) imidazolium thiosalicylate ([MTMSPI][TS]) ionic liquid was synthesized and the formation of [MTMSPI][TS] was confirmed through structural analysis using NMR, FTIR, IC, TGA, and Karl Fischer Titration. The [MTMSPI][TS] ionic liquid was then chemically immobilized on activated silica gel to produce a new thiosalicylate-based solid-supported ionic liquid (Si-TS-SSIL). The formation of these covalent bonds on Si-TS-SSIL was confirmed by solid-state NMR analysis. Meanwhile, BET analysis was performed to study the surface area of the activated silica gel and the prepared Si-TS-SSIL (before and after washing with solvent) with the purpose to show that all physically immobilized [MTMSPI][TS] has been washed off from Si-TS-SSIL, leaving only chemically immobilized [MTMSPI][TS] on Si-TS-SSIL before proceeding with removal study. The removal study of Pb(II) ions from an aqueous solution was carried out using Si-TS-SSIL as an extractant, whereby the amount of Pb(II) ions removed was determined by AAS. In this removal study, the experiments were carried out at a fixed agitation speed (400 rpm) and fixed amount of Si-TS-SSIL (0.25 g), with different contact times ranging from 2 to 250 min at room temperature. The maximum removal capacity was found to be 8.37 mg/g. The kinetics study was well fitted with the pseudo-second order model. Meanwhile, for the isotherm study, the removal process of Pb(II) ions was well described by the Freundlich isotherm model, as this model exhibited a higher correlation coefficient (R 2 ), i.e., 0.99, as compared to the Langmuir isotherm model.

Published

2023

2. Experimental and Mathematical Modelling of Factors Influencing Carbon Dioxide Absorption into the Aqueous Solution of Monoethanolamine and 1-Butyl-3-methylimidazolium Dibutylphosphate Using Response Surface Methodology (RSM).

Author

Azhar FNA, Taha MF, Mat Ghani SM, Ruslan MSH, and Md Yunus NM

Subjects

Carbon Dioxide, Imidazoles pharmacology, Ethanolamine, Ionic Liquids pharmacology

Abstract

This paper investigated the solubility of carbon dioxide (CO 2 ) in an aqueous solution of monoethanolamine (MEA) and 1-butyl-3-methylimidazolium dibutylphosphate ((BMIM)(DBP)) ionic liquid (IL) hybrid solvents. Aqueous solutions of MEA-(BMIM)(DBP) hybrid solvents containing different concentrations of (BMIM)(DBP) were prepared to exploit the amine's reactive nature, combined with the IL's non-volatile nature for CO 2 absorption. Response surface methodology (RSM) based on central composite design (CCD) was used to design the CO 2 solubility experiments and to investigate the effects of three independent factors on the solubility of CO 2 in the aqueous MEA-(BMIM)(DBP) hybrid solvent. The three independent factors were the concentration of (BMIM)(DBP) (0-20 wt.%), temperature (30 °C-60 °C) and pressure of CO 2 (2-30 bar). The experimental data were fitted to a quadratic model with a coefficient of determination ( R 2 ) value of 0.9791. The accuracy of the developed model was confirmed through additional experiments where the experimental values were found to be within the 95% confidence interval. From the RSM-generated model, the optimum conditions for CO 2 absorption in aqueous 30 wt% MEA-(BMIM)(DBP) were 20 wt% of (BMIM)(DBP), a temperature of 41.1 °C and a pressure of 30 bar.

Published

2022

3. Free Energy Calculation of CO2 in Cholinium-Based Amino Acid Ionic Liquids

Author

Salehin, Fitri Norizatie, Jumbri, Khairulazhar, Ramli, Anita, Kassim, Mohd Azlan, Taha, Mohd Faisal, Abdul Karim, Samsul Ariffin, editor, Abd Shukur, Mohd Fadhlullah, editor, Fai Kait, Chong, editor, Soleimani, Hassan, editor, and Sakidin, Hamzah, editor

Published

2021

4. Choline-Based Ionic Liquids-Incorporated IRMOF-1 for H2S/CH4 Capture: Insight from Molecular Dynamics Simulation.

Author

Ishak, Mohamad Adil Iman, Taha, Mohd Faisal, Wirzal, Mohd Dzul Hakim, Nordin, Muhammad Najib, Abdurrahman, Muslim, and Jumbri, Khairulazhar

Subjects

NATURAL gas, NATURAL gas pipelines, METAL-organic frameworks, MOLECULAR dynamics, SOLVATION, SOLUBILITY

Abstract

The removal of H2S and CH4 from natural gas is crucial as H2S causes environmental contamination, corrodes the gas stream pipelines, and decreases the feedstock for industrial productions. Many scientific researches have shown that the metal-organic framework (MOF)/ionic liquids (ILs) have great potential as alternative adsorbents to capture H2S. In this work, molecular dynamics (MD) simulation was carried out to determine the stability of ILs/IRMOF-1 as well as to study the solubility of H2S and CH4 gases in this ILs/IRMOF-1 hybrid material. Three choline-based ILs were incorporated into IRMOF-1 with different ratios of 0.4, 0.8, and 1.2% w/w, respectively, in which the most stable choline-based ILs/IRMOF-1 composite was analysed for H2S/CH4 solubility selectivity. Among the three choline-based ILs/IRMOF-1, [Chl] [SCN]/IRMOF-1 shows the most stable incorporation. However, the increment of ILs loaded in the IRMOF-1 significantly reduced the stability of the hybrid due to the crowding effect. Solvation free energy was then computed to determine the solubility of H2S and CH4 in the [Chl] [SCN]/IRMOF-1. H2S showed higher solubility compared to CH4, where its solubility declined with the increase of choline-based IL loading. [ABSTRACT FROM AUTHOR]

Published

2020