Improved Flooding Molecular Dynamics Analysis

Cirqueira, Leonardo; Stock, Letícia; Treptow, Werner

doi:10.1016/j.bpj.2019.11.896

Cited by 3 publications

(1 citation statement)

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“…MDs are becoming a powerful technique to study molecular structure and properties of organicinorganic clay interface [28][29][30].. The Forcite and CASTEP calculation modules implemented in Biovia Materials Studio (formerly Accelrys) software [31], were used to evaluate the nature of the interaction between the adsorbate (organic pollutant azo dye-Reactive Red 141) and the substrate (Iron-oxide mineral surface).…”

Section: Molecular Dynamics (Mds) Simulationmentioning

confidence: 99%

Computational study of the interaction between azo dye (RR141) and Hematite α-Fe2 O3 (111) Surface: A DFT and MDs Study

Belghiti

Mizeb

Salah

et al. 2023

Preprint

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The adsorptive removal of azo dye molecules from textile effluents by the powdered mineral hematite has been largely studied in the literature, but this mechanism of interaction with the mineral hematite surface is still to date not revealed, hence the need for a theoretical study. The crystal structure model of Hematite adopted is α − Fe2O3 (111). The DFT method and MDs(Molecular Dynamics simulations) have been employed to elucidate the mechanism of interaction. The azo-dye molecule chosen for this study is the reactive red RR141. Geometry minimization of RR141 was performed at the DFT / B3LYP / 6 −31+ +g(d,p) level of theory. The reactivity and performance of RR141-vacuum and RR141-aqueous media in isolated state were evaluated on basis of their planarity, global and local electronic properties as well as deformation ability to adhesion to the mineral surface. The Azo (> N− −N <) and hydroxyl (-O--H) groups are the main active centers for the adsorption of RR141 in a vacuum and aqueous media. Azo and hydroxyl groups of RR141 dye are electron donors, while the sulphonic acid (-SO3--Na+) group is an electron acceptor. The RR141 is found more reactive in the vacuum than in an aqueous medium. The interfacial interaction is the combined effect of the hydrogen bond and the interactions between Fe & −O−, C, −S−,= N− atoms. The whole system is interacting on the first layer through (π-π)-bonds in the nearly parallel adsorption geometries and through the single pair electrons of the heteroatoms.

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Section: Molecular Dynamics (Mds) Simulationmentioning

confidence: 99%