Polymerized stimuli-responsive microgels for the removal of organic dye from water
Title | Polymerized stimuli-responsive microgels for the removal of organic dye from water |
Publication Type | Journal Article |
Year of Publication | 2023 |
Authors | Pany, B, Majundar, AGhosh, Mohanty, M, Fyis, KP, Dey, T, Tripathy, G, Bhat, S, Yamanaka, J, Mohanty, PS |
Journal | Journal of Molecular Liquids |
Volume | 375 |
Pagination | 121267 |
Date Published | APR |
Type of Article | Article |
ISSN | 0167-7322 |
Keywords | dynamic light scattering, Molecular docking, PNIPAM microgels, Removal of organic pollutants, Stimuli -responsive microgels |
Abstract | Polymerized hydrogel materials (PGM) containing uniform-sized stimuli-responsive microgel particles could be promising alternatives for solution-based microgels to remove organic dyes from water. In the current work, PGM is prepared using Poly(N-isopropylacrylamide-co-acrylic acid) based anionic microgels and their ability for uptake and release studies with an oppositely charged dye, methylene blue (MB) is carried out using UV-vis spectroscopy. The mechanism of dye adsorption is understood at a single particle level using light scattering, and zeta potential and the contributions from different molecular interactions among dye molecules and constituting entities of microgels are obtained from molecular docking studies. The maximum dye uptake by PGM is around 80 % in the swollen state (at pH 7 and 20 degrees C). In contrast, the dye release studies in the deswollen state (at pH 3 and 50 degrees C) show a decrease in the release efficiency from 87 % to 63 % of the total dye adsorbed in 4-repeated cycles. The adsorption isotherm follows a sigmoidal (S) model that has been majorly used in different multi-layer adsorption systems. Extensive dynamic and static light scattering studies demonstrate a deswelling of hydrody-namic radius and core-shell radius of microgels at low temperatures (20 degrees C) induced by dye adsorption. At higher temperatures, the dye-adsorbed microgels have a higher hydrodynamic radius than the pure microgels due to the remaining dye molecules within the microgel that do not release even in the deswollen state. Molecular docking studies show that electrostatic interaction dominates between COO- and MB and van der Waals/hydrophobic dominates for MB-NIPAM and MB-COOH docking complex respectively. Our work covering adsorption/desorption properties of the material to the single-particle level can provide a better understanding in formulating reusable smart materials for the remediation of different water pollutants.(c) 2023 Elsevier B.V. All rights reserved. |
DOI | 10.1016/j.molliq.2023.121267 |
Type of Journal (Indian or Foreign) | Foreign |
Impact Factor (IF) | 6 |
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