The Molecular Mechanism of Iron(III) Oxide Nucleation

Scheck, Johanna; Wu, Baohu; Drechsler, Markus; Rosenberg, Rose; Driessche, Alexander E. S. Van; Stawski, Tomasz M.; Gebauer, Denis

doi:10.1021/acs.jpclett.6b01237

Cited by 68 publications

(125 citation statements)

References 38 publications

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“…[27] Here, the titrationc urve ( Figure 1) can be subdivided into at least two distinctr egionst hat can be regardeda sp re-and postnucle-ation stages. [25] During the prenucleation stage, only ligand exchange and olation bridging processes take place and lead to the formation of ad ynamic population of olation PNCs. [25,27] Phase separationo ccurs on upwards bending of the curve, with significant deviation from the initially linear profile (fine dottedl ine in Figure 1).…”

Section: Resultsmentioning

confidence: 99%

“…Recently,i th as been shownt hat the early stages of iron(III) oxide formation at room temperaturea nd low drivingf orce for phases eparation-that is, at low degrees of supersaturation, which are apparent from significant durationso fp renucleation stateso fm etastable equilibrium on slow mixing of solutionsmechanistically proceeda ccording to the notions of the socalled prenucleation cluster (PNC) pathway. [25,26] In the case of iron (oxyhydr)oxides,t hermodynamically stable PNCs are dynamico lation polymers that qualify as solutes and are part of the homogeneous,m etastable solution. On phase separation, the formation of oxo bridgesi nt he clusters renders them less dynamicd ue to the stronger bonds bridgingthe iron(III) centers.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Nucleation of Hematite: A Nonclassical Mechanism

Scheck

Fuhrer

et al. 2019

Chemistry A European J

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Hematite (α‐Fe2O3) is thermodynamically stable under ambient conditions, of vast geological importance, and widely used in applications, for example, as corrosion protection and as a pigment. It forms at elevated temperatures, whereas room‐temperature reactions typically yield metastable akaganéite or ferrihydrite. The mechanistic key changes underlying this observation were explored in the present study. The entropic contribution to the prenucleation hydrolysis reaction categorically implies the presence of prenucleation clusters (PNCs) as fundamental precursors. The formation of hematite is then due to a change in the reaction mechanism above approximately 50 °C, whereby the reaction limitation towards oxolation in phase‐separated clusters is overcome. A model that rationalizes the occurrence of hematite, akaganéite, and ferrihydrite based on the chemistry of olation PNCs is proposed. Supersaturation and the temperature dependence of olation and oxolation rates from monomeric precursors are irrelevant in this nonclassical mechanism.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Nucleation of Hematite: A Nonclassical Mechanism

Scheck

Fuhrer

et al. 2019

Chemistry A European J

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“…Mechanistic contributions of cluster species are recognized for several metals, metal oxides and semiconductors such as CdS, iridium, iron (oxyhydr) oxides, silver and titanium oxide particles . Conventionally addressed as ‘nanoclusters’, particles smaller than 2 nm typically exhibit atomic level rearrangements and distinct physical properties in relation to larger solid particles .…”

Section: On the Nature Of Materials Precursorsmentioning

confidence: 99%

From Solute, Fluidic and Particulate Precursors to Complex Organizations of Matter

Rao

Cölfen

2018

The Chemical Record

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The organization of matter from its constitutive units recruits intermediate states with distinctive degrees of self-association and molecular order. Existing as clusters, droplets, gels as well as amorphous and crystalline nanoparticles, these precursor forms have fundamental contributions towards the composition and structure of inorganic and organic architectures. In this personal account, we show that the transitions from atoms, molecules or ionic species to superstructures of higher order are intertwined with the interfaces and interactions of precursor and intermediate states. Structural organizations distributed across different length scales are explained by the multistep nature of nucleation and crystallization, which can be guided towards functional hybrid materials by the strategic application of additives, templates and reaction environments. Thus, the non-classical pathways for material formation and growth offer conceptual frameworks for elucidating, inducing and directing fascinating material organizations of biogenic and synthetic origins.

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“…[1] Nevertheless, despite the broad interest and great efforts from many disciplines, the detailed mechanism of iron oxide nucleation and phase transformation, and the roles of various evolved species remain obscure. Recently, it was shown that at low driving force for phase separation (i.e., low pH and iron concentration) olation polymers can be regarded as stable pre-nucleation clusters (PNCs), where the onset of oxolation within the PNCs triggers a decrease in their dynamics, [2] which is the chemical basis of a phase separation event according to the notions of the PNC pathway. [3] The mechanism is consistent with the chemistry of iron oxides that has been extensively studied for decades, where the hydrolysis of iron salts in aqueous solutions produces very small colloidal particles (also termed as polycations, clusters, or primary particles) with a size of 1-4 nm.…”

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confidence: 99%

“…The AIO-PCDA cluster has a well-defined core-shell structure with the chelation of Fe by gauche PCDA chains, and the co-existence of Fe 2+ and Fe 3+ was also identified. Thermal gravimetric analysis (TGA, Figure S14 Figure S15) further detected the largest species to be Fe 9 O 3 -(OH) 16 ·6 H 2 O:(PCDA) 2 , and with it, we constructed the structure of an AIO-PCDA cluster, as shown in Figure S16. The AIO core has an approximate size of 1.1 nm (Figure S17), which is apparently smaller than the ligand-free AIO cluster (ca.…”

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Alignment of Amorphous Iron Oxide Clusters: A Non‐Classical Mechanism for Magnetite Formation

2017

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Despite numerous studies on the nucleation and crystallization of iron (oxyhydr)oxides, the roles of species developing during the early stages, especially primary clusters and intermediate amorphous particles, are still poorly understood. Herein, both ligand-free and ligand-protected amorphous iron oxide (AIO) clusters (< 2 nm) were synthesized as precursors for magnetite formation. Thermal annealing can crystallize the clusters into magnetite particles, and AIO bulk phases with domains of pre-aligned clusters are found to be direct precursors to crystals, suggesting a non-classical aggregation-based pathway that differs from the reported oriented attachment or particle accretion mechanisms.

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The Molecular Mechanism of Iron(III) Oxide Nucleation

Cited by 68 publications

References 38 publications

Nucleation of Hematite: A Nonclassical Mechanism

Nucleation of Hematite: A Nonclassical Mechanism

From Solute, Fluidic and Particulate Precursors to Complex Organizations of Matter

Alignment of Amorphous Iron Oxide Clusters: A Non‐Classical Mechanism for Magnetite Formation

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