Molecular Dynamics Simulation Study of the Early Stages of Nucleation of Iron Oxyhydroxide Nanoparticles in Aqueous Solutions

Zhang, Hengzhong; Waychunas, Glenn A.; Banfield, Jillian F.

doi:10.1021/acs.jpcb.5b03801

Cited by 40 publications

(44 citation statements)

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“…The catalyst prepared by method 3 provided a higher yield of O 2 (65 %) than the catalysts prepared by methods 1 and 2 (60 and 54 % of the stoichiometric yield, respectively). The results obtained can be understood based on the data reported by H. Zhang et al [27] who used the method of molecular dynamics for studying the process of the formation of primary particles of hydroxo compounds. The author established that disordered 1-2 nm hydroxide clusters are only formed at low concentrations of the hydrolyzed salts.…”

Section: Resultsmentioning

confidence: 79%

“…[35] Some literature data were used for modeling the iron hydroxide cluster. Zhang and co-authors [27] used centroid molecular dynamics with combined set of force fields [36,37] and additional central force model for water [38] for modeling the process of nucleation of Fe III hydroxide. These simulation results showed that during the early stages of hydrolysis there is occurs the coagulation processes and formation of amorphous primary hydroxide particles (1-2 nm).…”

Section: Catalyst Modeling By a Molecular Mechanics Approachmentioning

confidence: 99%

“…where E 1 is the total energy of hydrated iron hydroxide cluster (Fe27 O 27 OH 27 + 1189 H 2 O); E 2 is the total energy of hydrated starch molecule ((C 6 H 10 O 5 ) 50 + 1189 H 2 O); E 3 is the total energy of hydrated hydroxide stabilized with starch molecule (Fe 27 O 27 OH 27 + (C 6 H 10 O 5 ) 50 + 1189 H 2 O)…”

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confidence: 99%

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Colloidal Fe^III, Mn^III, Co^III, and Cu^II Hydroxides Stabilized by Starch as Catalysts of Water Oxidation Reaction with One Electron Oxidant Ru(bpy)₃³⁺

et al. 2019

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Colloidal catalysts for oxidation of water to dioxygen, which are stable on storage and under the reaction conditions, are synthesized based on Co III , Mn III , Fe III and Cu II hydroxides. Stabilization of the colloids with dextrated starch allows the process of hydroxide ageing to be stopped at the stage of the formation of primary nuclei (ca. 2-3 nm from transmission electron microscopy data). Molecular mechanics and dynamic light scattering studies indicate a core-shell type structure of the catalysts, where the hydroxide core is stabilized by the molecular starch network (ca. 5-7 nm). The colloidal catalysts are highly efficient in oxidizing water with one electron oxidant Ru(bpy) 3 3 + at pH 7 to 10. The influence of pH, catalyst concentration, and buffer nature on the oxygen yield is studied. The maximal yields are 72, 53, and 78 % over Fe-, Mn-and Cocontaining catalysts, respectively, and turnover numbers are 7.8; 54 and 360, respectively. The Cu-containing catalyst is poorly effective to the water oxidation (the maximal yield is 28 % O 2 ). The synthesized catalysts are of interest for stopped-flow kinetic studies of the mechanism of the water oxidation and as precursors for anchoring nanosized hydroxides onto various supports in order to develop biomimetic systems for artificial photosynthesis.[a] A. S. Chikunov, Prof. O. P. Taran, Prof. V. N. Parmon Boreskov Institute of Catalysis (BIC SB RAS) 630090, Novosibirsk, Lavrentieva ave. 5 (Russian Federation)

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Section: Resultsmentioning

confidence: 79%

Section: Catalyst Modeling By a Molecular Mechanics Approachmentioning

confidence: 99%

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Colloidal Fe^III, Mn^III, Co^III, and Cu^II Hydroxides Stabilized by Starch as Catalysts of Water Oxidation Reaction with One Electron Oxidant Ru(bpy)₃³⁺

et al. 2019

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“…In many experimental settings, cluster-and particle-based pathways have been observed for iron() oxide nucleation and growth. 2,[5][6][7] In the early stages of iron() hydrolysis, small species in the size range of 1-4 nm occur. Such polymeric clusters aggregate to form the different crystalline materials.…”

Section: Introductionmentioning

confidence: 99%

“…Such polymeric clusters aggregate to form the different crystalline materials. 2,5,6,8 It was recently proposed that iron() (oxyhydr)oxide precipitation in such cluster-based pathways can be described within the notions of the so-called pre-nucleation cluster (PNC) pathway. 9 In this model, in contrast to the classical nucleation picture, a) J. Konsek, J. Schwaderer, and S. M. Stadler contributed equally to this work.…”

Section: Introductionmentioning

confidence: 99%

Polyaspartic acid facilitates oxolation within iron(iii) oxide pre-nucleation clusters and drives the formation of organic-inorganic composites

Scheck

Drechsler

et al. 2016

The Journal of Chemical Physics

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The interplay between polymers and inorganic minerals during the formation of solids is crucial for biomineralization and bio-inspired materials, and advanced material properties can be achieved with organic-inorganic composites. By studying the reaction mechanisms, basic questions on organic-inorganic interactions and their role during material formation can be answered, enabling more target-oriented strategies in future synthetic approaches. Here, we present a comprehensive study on the hydrolysis of iron(iii) in the presence of polyaspartic acid. For the basic investigation of the formation mechanism, a titration assay was used, complemented by microscopic techniques. The polymer is shown to promote precipitation in partly hydrolyzed reaction solutions at the very early stages of the reaction by facilitating iron(iii) hydrolysis. In unhydrolyzed solutions, no significant interactions between the polymer and the inorganic solutes can be observed. We demonstrate that the hydrolysis promotion by the polymer can be understood by facilitating oxolation in olation iron(iii) pre-nucleation clusters. We propose that the adsorption of olation pre-nucleation clusters on the polymer chains and the resulting loss in dynamics and increased proximity of the reactants is the key to this effect. The resulting composite material obtained from the hydrolysis in the presence of the polymer was investigated with additional analytical techniques, namely, scanning and transmission electron microscopies, light microscopy, atomic force microscopy, zeta potential measurements, dynamic light scattering, and thermogravimetric analyses. It consists of elastic, polydisperse nanospheres, ca. 50-200 nm in diameter, and aggregates thereof, exhibiting a high polymer and water content.

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Ausrichtung amorpher Eisenoxid‐Cluster: ein nichtklassischer Mechanismus für die Magnetitbildung

2017

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Obwohl schon viele Studien auf dem Gebiet der Nukleation und Kristallisation von Eisen(oxyhydr)oxiden durchgeführt wurden, ist die Rolle der Spezies,die sich in den frühen Stadien entwickeln, besonders primäre Cluster und amorphe Übergangspartikel, immer nochschlecht verstanden. Hier wurden sowohl ligandenfreie als auchligandengeschützte amorphe Eisenoxid-Cluster ("amorphous iron oxide", AIO, < 2nm) als Vorstufen fürd ie Magnetitbildung synthetisiert. DurchT empern kçnnen die Cluster zu Magnetitpartikeln kristallisieren, und es wurde festgestellt, dass die AIO-Bulkphase mit Domänen von vororientierten Clustern eine direkte Vorstufe zum Kristall ist. Dies weist auf einen nichtklassischen aggregationsbasierten Reaktionspfad hin, welcher sich von der bisher berichteten orientierten Anlagerung oder dem Partikelanlagerungsmechanismus unterscheidet.

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Molecular Dynamics Simulation Study of the Early Stages of Nucleation of Iron Oxyhydroxide Nanoparticles in Aqueous Solutions

Cited by 40 publications

References 47 publications

Colloidal Fe^III, Mn^III, Co^III, and Cu^II Hydroxides Stabilized by Starch as Catalysts of Water Oxidation Reaction with One Electron Oxidant Ru(bpy)₃³⁺

Colloidal Fe^III, Mn^III, Co^III, and Cu^II Hydroxides Stabilized by Starch as Catalysts of Water Oxidation Reaction with One Electron Oxidant Ru(bpy)₃³⁺

Polyaspartic acid facilitates oxolation within iron(iii) oxide pre-nucleation clusters and drives the formation of organic-inorganic composites

Ausrichtung amorpher Eisenoxid‐Cluster: ein nichtklassischer Mechanismus für die Magnetitbildung

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Molecular Dynamics Simulation Study of the Early Stages of Nucleation of Iron Oxyhydroxide Nanoparticles in Aqueous Solutions

Cited by 40 publications

References 47 publications

Colloidal FeIII, MnIII, CoIII, and CuII Hydroxides Stabilized by Starch as Catalysts of Water Oxidation Reaction with One Electron Oxidant Ru(bpy)33+

Colloidal FeIII, MnIII, CoIII, and CuII Hydroxides Stabilized by Starch as Catalysts of Water Oxidation Reaction with One Electron Oxidant Ru(bpy)33+

Polyaspartic acid facilitates oxolation within iron(iii) oxide pre-nucleation clusters and drives the formation of organic-inorganic composites

Ausrichtung amorpher Eisenoxid‐Cluster: ein nichtklassischer Mechanismus für die Magnetitbildung

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Colloidal Fe^III, Mn^III, Co^III, and Cu^II Hydroxides Stabilized by Starch as Catalysts of Water Oxidation Reaction with One Electron Oxidant Ru(bpy)₃³⁺

Colloidal Fe^III, Mn^III, Co^III, and Cu^II Hydroxides Stabilized by Starch as Catalysts of Water Oxidation Reaction with One Electron Oxidant Ru(bpy)₃³⁺