Strategy to control magnetic coercivity by elucidating crystallization pathway-dependent microstructural evolution of magnetite mesocrystals

Park, Bum Chul; Cho, Jiung; Kim, Myeong Soo; Ko, Min Jun; Pan, Liqing; Na, Jin Yeong; Kim, Young Keun

doi:10.1038/s41467-019-14168-0

Cited by 27 publications

(24 citation statements)

References 46 publications

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“…The polymorphism of ferric oxyhydroxide as an intermediate significantly affects the crystallisation mechanism of Fe 3 O 4 mesocrystals 17 , 18 , 23 – 25 . We recently identified two Fe 3 O 4 crystallisation pathways starting from either lepidocrocite or goethite and revealed that Fe 3 O 4 mesocrystals grew via OA only in the former case 23 . These pathways are competitively responsible for Fe 3 O 4 growth and can be selectively regulated according to the initial [OH – ]/[Fe 3+ ] ratio.…”

Section: Resultsmentioning

confidence: 99%

Surface-ligand-induced crystallographic disorder–order transition in oriented attachment for the tuneable assembly of mesocrystals

Park

Kim³

et al. 2022

Nat Commun

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In the crystallisation of nanomaterials, an assembly-based mechanism termed ‘oriented attachment’ (OA) has recently been recognised as an alternative mechanism of crystal growth that cannot be explained by the classical theory. However, attachment alignment during OA is not currently tuneable because its mechanism is poorly understood. Here, we identify the crystallographic disorder-order transitions in the OA of magnetite (Fe3O4) mesocrystals depending on the types of organic surface ligands on the building blocks, which produce different grain structures. We find that alignment variations induced by different surface ligands are guided by surface energy anisotropy reduction and surface deformation. Further, we determine the effects of alignment-dependent magnetic interactions between building blocks on the global magnetic properties of mesocrystals and their chains. These results revisit the driving force of OA and provide an approach for chemically controlling the crystallographic order in colloidal nanocrystalline materials directly related to grain engineering.

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Section: Resultsmentioning

confidence: 99%

Surface-ligand-induced crystallographic disorder–order transition in oriented attachment for the tuneable assembly of mesocrystals

Park

Kim³

et al. 2022

Nat Commun

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“…Surface oxygen vacancies can serve as the activation sites of O 2 molecules, probably reducing the energy barrier of oxygen species regeneration. Meanwhile, the Ce–Ce homogeneous interface and bulk oxygen vacancies reduce the activation and migration barriers of reactive oxygen species . Therefore, CeO 2 –MC tends to exhibit much better catalytic performance.…”

Section: Resultsmentioning

confidence: 99%

“…Meanwhile, the Ce−Ce homogeneous interface and bulk oxygen vacancies reduce the activation and migration barriers of reactive oxygen species. 53 Therefore, CeO 2 −MC tends to exhibit much better catalytic performance.…”

Section: Structural Defects and Oxygen Vacanciesmentioning

confidence: 99%

Boosting the Catalytic Performance of CeO₂ in Toluene Combustion via the Ce–Ce Homogeneous Interface

Liu

et al. 2021

Environ. Sci. Technol.

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Catalytic combustion is an advanced technology to eliminate industrial volatile organic compounds such as toluene. In order to replace the expensive noble metal catalysts and avoid the aggregation phenomenon occurring in traditional heterogeneous interfaces, designing homogeneous interfaces can become an emerging methodology to enhance the catalytic combustion performance of metal oxide catalysts. A mesocrystalline CeO2 catalyst with abundant Ce–Ce homogeneous interfaces is synthesized via a self-flaming method which exhibits boosted catalytic performance for toluene combustion compared with traditional CeO2, leading to a ∼40 °C lower T90. The abundant Ce–Ce homogeneous interfaces formed by both highly ordered stacking and small grain size endow the CeO2 mesocrystal with superior redox property and oxygen storage capacity via forming various oxygen vacancies. Surface and bulk oxygen vacancies generate and activate crucial oxygen species, while interfacial oxygen vacancies further promote the reaction behavior of oxygen species (i.e., activation, regeneration, and migration), causing the splitting of redox property toward lower temperature. These properties facilitate aromatic ring decomposition, the important rate-determining step, thus contributing to toluene catalytic degradation to CO2. This work may shed insights into the catalytic effects of homogeneous interfaces in pollutant removal and provide a strategy of interfacial defect engineering for catalyst development.

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“…The oxolation process is the formation of oxo bridges (−Fe–O–Fe−) accompanied by expelling of molecular water . The primary colloidal particles then aggregate, which allows the heterogeneous nucleation of anhydrous iron oxides, including MNPs. ,,,,− This advanced model for magnetite nucleation has been proposed based on data acquired from time-resolved and/or conventional measurements using sophisticated analytical/reactor tools such as liquid-cell transmission electron microscopy (TEM), cryo-TEM, microfluidic reactors, titration reactors, dynamic light scattering, analytical ultracentrifugation, synchrotron-based X-ray diffraction (XRD), small- and wide-angle X-ray scattering (SAXS/WAXS), atomic force microcopy, and field-emission scanning electron microscopy (FESEM). In these experimental studies, direct nucleation of MNPs from ionic solutions has been rarely invoked and measured. , Two main approaches have been proposed to explain the formation of magnetite.…”

Section: Introductionmentioning

confidence: 99%

Direct and Indirect Nucleation of Magnetite Nanoparticles from Solution Revealed by Time-Resolved Raman Spectroscopy

Montes-Hernandez

Findling

Renard

2021

Crystal Growth & Design

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Magnetite is a widespread inorganic or bio-mineral with very specific and extraordinary chemical properties in terms of acid-base and oxidation-reduction behavior, thermal stability and oxygen mobility. Despite the existence of many synthesis methods, the formation mechanisms of this mineral are actively investigated and frequently debated. The co-precipitation reaction (2Fe 3+ + Fe 2+ + 8OH − → Fe3O4 + 4H2O) is the most widespread method to synthesize magnetite under laboratory conditions and at industrial scale. However, the early stages of magnetite formationnucleation events and precursors/transient phases formationare still questioned and their kinetics is poorly characterized. Here, we perform two series of experiments that differ by how the solutions are mixed: i) injection of an iron-rich solution into an alkaline aqueous solution; and ii) injection of an alkaline solution into an iron-rich solution. We show that dynamic in situ Raman spectroscopy provides invaluable information on the direct and indirect nucleation of magnetite nanoparticles (<15nm) from aqueous solution. When a mixed-valent iron solution (0.5M Fe 2+ + 0.5M Fe 3+ ) is injected (2.3 or 12 ml/minute) into an alkaline solution (4M of NaOH); dark colloidal particles form instantaneously and the magnetite signal is rapidly detected in Raman spectra after 3 or 7 minutes, depending of the injection rate. This result demonstrates that the mixed-valent iron is instantaneously dehydrated leading to the formation of magnetite-like colloidal (or primary) particles peaking in the range 674-678 cm -1 in the Raman spectra, with peak position stabilizing rapidly at 673 cm -1 . Conversely, when alkaline solution is added into the mixed-valent iron solution, Raman spectroscopy reveals a complex reaction mechanism and kinetics. Firstly, iron dehydration (315 cm -1 ) and formation of green rust (500-503 cm -1 ) as transient phase related to olation process are detected and interpreted by the formation of hydroxo bridges accompanied with 3 expelling of molecular water. Secondly, green rust and available ferric iron (ions or colloids) react to nucleate magnetite nanoparticles via an oxolation process related to the formation of oxo bridges accompanied with the expelling of hydroxylated water. We also quantified the nucleation time of magnetite and the hydrophilic-to-hydrophobic change in the suspension by the temporal behavior of bending mode of molecular water. Our results show that, under our experimental conditions, amorphous transient phases during direct or indirect magnetite formation from ionic solutions do not exist or that such phases do not show a specific Raman signature.

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Strategy to control magnetic coercivity by elucidating crystallization pathway-dependent microstructural evolution of magnetite mesocrystals

Cited by 27 publications

References 46 publications

Surface-ligand-induced crystallographic disorder–order transition in oriented attachment for the tuneable assembly of mesocrystals

Surface-ligand-induced crystallographic disorder–order transition in oriented attachment for the tuneable assembly of mesocrystals

Boosting the Catalytic Performance of CeO₂ in Toluene Combustion via the Ce–Ce Homogeneous Interface

Direct and Indirect Nucleation of Magnetite Nanoparticles from Solution Revealed by Time-Resolved Raman Spectroscopy

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Strategy to control magnetic coercivity by elucidating crystallization pathway-dependent microstructural evolution of magnetite mesocrystals

Cited by 27 publications

References 46 publications

Surface-ligand-induced crystallographic disorder–order transition in oriented attachment for the tuneable assembly of mesocrystals

Surface-ligand-induced crystallographic disorder–order transition in oriented attachment for the tuneable assembly of mesocrystals

Boosting the Catalytic Performance of CeO2 in Toluene Combustion via the Ce–Ce Homogeneous Interface

Direct and Indirect Nucleation of Magnetite Nanoparticles from Solution Revealed by Time-Resolved Raman Spectroscopy

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Boosting the Catalytic Performance of CeO₂ in Toluene Combustion via the Ce–Ce Homogeneous Interface