Growth Mechanism of Highly Branched Titanium Dioxide Nanowires via Oriented Attachment

Li, Dongsheng; Soberanis, Frank; Jia, Fang; Hou, Wenting; Wu, Jianzhong; Kisailus, David

doi:10.1021/cg301388e

Cited by 71 publications

(87 citation statements)

References 35 publications

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“…This dependence can even invert the sequence of polymorph stability relative to that observed for the bulk phases (58). Thus, primary particles may be a polymorph that is only stable at a small size, while the secondary particles have the structure of the stable bulk form (34,56,57,60). That is, the free-energy barrier to nucleating small particles possessing a form that is metastable in the bulk phase will be lower than the barrier to nucleating particles of the same size possessing the stable bulk form.…”

Section: The Influence Of Surface Energy On Pathwaysmentioning

confidence: 94%

“…1 and 4). Precursors can include one or more solid amorphous phases (10,12,14,15,18,30,46,64,65), dense liquids or gels (21,49,53), or crystalline nanoparticles (30,57,60,63). Each results in a distinct growth history, but whether or not the final outcomes are also distinct should depend on the extent to which monomer-by-monomer addition competes with the particle-attachment pathways and coarsening or recrystallization processes modify the structure and morphology of the growing crystal.…”

Section: Precursor Phasesmentioning

confidence: 99%

“…In some cases, increasing size can result in decreased internal strain and defect content (82). Finally, in systems for which there is a switch in phase stability with particle size, as discussed above, nanoparticles of one phase may initially form and transform to the bulk phase as they aggregate and grow in size (34,56,57,60). For example ~1-nm ferrihydrite-like primary particles structurally rearrange upon attachment to the surface of magnetite crystals to merge with the magnetite crystal structure (57).…”

Section: Crystalline Nanoparticlesmentioning

confidence: 99%

See 2 more Smart Citations

Crystallization by particle attachment in synthetic, biogenic, and geologic environments

Yoreo

Gilbert

Sommerdijk

et al. 2015

Science

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Field and laboratory observations show that crystals commonly form by the addition and attachment of particles that range from multi-ion complexes to fully formed nanoparticles. The particles involved in these nonclassical pathways to crystallization are diverse, in contrast to classical models that consider only the addition of monomeric chemical species. We review progress toward understanding crystal growth by particle-attachment processes and show that multiple pathways result from the interplay of free-energy landscapes and reaction dynamics. Much remains unknown about the fundamental aspects, particularly the relationships between solution structure, interfacial forces, and particle motion. Developing a predictive description that connects molecular details to ensemble behavior will require revisiting long-standing interpretations of crystal formation in synthetic systems, biominerals, and patterns of mineralization in natural environments.

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Section: The Influence Of Surface Energy On Pathwaysmentioning

confidence: 94%

Section: Precursor Phasesmentioning

confidence: 99%

Section: Crystalline Nanoparticlesmentioning

confidence: 99%

See 1 more Smart Citation

Crystallization by particle attachment in synthetic, biogenic, and geologic environments

Yoreo

Gilbert

Sommerdijk

et al. 2015

Science

1,618

1,637

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show abstract

“…Among the numerous styles of CPA, none has garnered more attention than oriented attachment (OA) by which crystalline nanoparticles assemble into larger single-crystal structures through attachment on coaligned crystal faces (4,5). OA often leads to formation of hierarchical structures, such as highly branched nanowires (6), tetrapods (7), and nanoparticle superlattices (8), endowed with unique properties (9) that are inexorably tied to this nonclassical process of crystallization.…”

mentioning

confidence: 99%

“…OA has been inferred for metals (10), semiconductors (11), and insulating oxides (6); it has been directly observed via liquid phase transmission electron microscopy (LP-TEM) (5), and the evolution of particle distributions during OA has been captured with cryogenic TEM (12). OA is highly dependent on solution conditions, including pH, ionic strength, and temperature, and is marked by two important stages.…”

mentioning

confidence: 99%

Trends in mica–mica adhesion reflect the influence of molecular details on long-range dispersion forces underlying aggregation and coalignment

Chun

Xiao

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Oriented attachment of nanocrystalline subunits is recognized as a common crystallization pathway that is closely related to formation of nanoparticle superlattices, mesocrystals, and other kinetically stabilized structures. Approaching particles have been observed to rotate to achieve coalignment while separated by nanometer-scale solvent layers. Little is known about the forces that drive coalignment, particularly in this "solvent-separated" regime. To obtain a mechanistic understanding of this process, we used atomic-forcemicroscopy-based dynamic force spectroscopy with tips fabricated from oriented mica to measure the adhesion forces between mica (001) surfaces in electrolyte solutions as a function of orientation, temperature, electrolyte type, and electrolyte concentration. The results reveal an ∼60°periodicity as well as a complex dependence on electrolyte concentration and temperature. A continuum model that considers the competition between electrostatic repulsion and van der Waals attraction, augmented by microscopic details that include surface separation, water structure, ion hydration, and charge regulation at the interface, qualitatively reproduces the observed trends and implies that dispersion forces are responsible for establishing coalignment in the solvent-separated state.orientation-dependent interparticle forces | dynamic force spectroscopy | atomic force microscopy | solvent structure | DLVO theory C rystallization by particle attachment (CPA) is a common mechanism by which single crystals form in solutions (1). In contrast to classical growth processes of monomer-by-monomer addition and Ostwald ripening, CPA occurs through assembly of higher-order species ranging from multi-ion complexes (2) and polymeric clusters (3) to fully formed nanocrystals. Among the numerous styles of CPA, none has garnered more attention than oriented attachment (OA) by which crystalline nanoparticles assemble into larger single-crystal structures through attachment on coaligned crystal faces (4, 5). OA often leads to formation of hierarchical structures, such as highly branched nanowires (6), tetrapods (7), and nanoparticle superlattices (8), endowed with unique properties (9) that are inexorably tied to this nonclassical process of crystallization.OA has been inferred for metals (10), semiconductors (11), and insulating oxides (6); it has been directly observed via liquid phase transmission electron microscopy (LP-TEM) (5), and the evolution of particle distributions during OA has been captured with cryogenic TEM (12). OA is highly dependent on solution conditions, including pH, ionic strength, and temperature, and is marked by two important stages. In the first stage, particles approach one another but do not make contact; rather they remain separated by an intervening solvent layer of O(1) nm in thickness (5). This solvent-separated state can occur on such an extensive scale that a kinetically stabilized particle array-sometimes referred to as a mesocrystal-is formed in which particles are crystallographically...

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Synthesis of Highly Branched Zinc Oxide Nanowires

Hou

Lancaster

et al. 2014

Ceramic Transactions Series

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Growth Mechanism of Highly Branched Titanium Dioxide Nanowires via Oriented Attachment

Cited by 71 publications

References 35 publications

Crystallization by particle attachment in synthetic, biogenic, and geologic environments

Crystallization by particle attachment in synthetic, biogenic, and geologic environments

Trends in mica–mica adhesion reflect the influence of molecular details on long-range dispersion forces underlying aggregation and coalignment

Synthesis of Highly Branched Zinc Oxide Nanowires

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