Iron Precursor Decomposition in the Magnesium Combustion Flame: A New Approach for the Synthesis of Particulate Metal Oxide Nanocomposites

Gheisi, Amir R.; Niedermaier, Matthias; Tippelt, Gerold; Lottermoser, Werner; Bernardi, Johannes; Diwald, Oliver

doi:10.1002/ppsc.201700109

Cited by 10 publications

(29 citation statements)

References 48 publications

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“…We start with as‐synthesized powders of In−Mg−O nanocomposite particles that were grown using a newly developed chemical vapor synthesis approach (Figure S1, Supporting Information) ,. The process employs the decomposition of an indium organic precursor inside the Mg vapor combustion flame which is associated with a combustion reaction that exhibits sufficiently high exothermicity and high temperatures (≈2600 K) to completely convert the precursor components into metal oxides.…”

Section: Resultssupporting

confidence: 82%

“…As a result, less regular surface features remain on the surface and the particles adopt a roundish shape without sharp edge and corner features. A similar situation was previously observed for Fe 3+ doped MgO nanoparticles, where Fe 3+ ions in the near‐surface region of the nanocrystals promote the formation of terraces, protrusions and step edges of multiple heights. Regular {100} faces being energetically favored in pure MgO nanoparticle systems are significantly less abundant in these doped systems.…”

Section: Resultsmentioning

confidence: 99%

“…We start with as-synthesized powders of InÀ MgÀ O nanocomposite particles that were grown using a newly developed chemical vapor synthesis approach (Figure S1, Supporting Information). [8,16] The process employs the decomposition of an indium organic precursor inside the Mg vapor combustion flame which is associated with a combustion reaction that exhibits sufficiently high exothermicity and high temperatures ( � 2600 K) to completely convert the precursor components into metal oxides. Using this approach, we obtain powders of highly dispersed and crystalline nanoparticles ( Figure 1a) with an extremely homogeneous distribution of size ( Figure 1b) and composition ( Figure S2, Supporting Information).…”

Section: Resultsmentioning

confidence: 99%

“…In−Mg−O nanoparticles were produced in a modified metalorganic chemical vapor synthesis (MOCVS) approach (Figure S1, Supporting Information), which provides high control over concentration and homogeneous distribution of indium in In−Mg−O nanoparticle powders ,. In this approach, an indium organic vapor decomposes in the combustion flame related to the Mg metal vapor oxidation reaction with oxygen inside a hot wall reactor system and under reduced pressures.…”

Section: Methodsmentioning

confidence: 99%

“…InÀ MgÀ O nanoparticles were produced in a modified metalorganic chemical vapor synthesis (MOCVS) approach (Figure S1, Supporting Information), which provides high control over concentration and homogeneous distribution of indium in InÀ MgÀ O nanoparticle powders. [8,16] In this approach, an indium organic vapor decomposes in the combustion flame related to the Mg metal vapor oxidation reaction with oxygen inside a hot wall reactor system and under reduced pressures. The two-zone reactor system ( Figure S1, Supporting Information) consists of two quartz glass tubes, which are mounted concentrically inside a heating coil (first heating zone with an operation temperature T1) followed by a ceramic tube furnace (second heating zone with an operation temperature T2).…”

Section: Methodsmentioning

confidence: 99%

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Impurity Segregation and Nanoparticle Reorganization of Indium Doped MgO Cubes

et al. 2019

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Metal oxide nanocomposites are non‐equilibrium solids and promising precursors for functional materials. Annealing of such materials can provide control over impurity segregation and, depending on the level of consolidation, represents a versatile approach to engineer free surfaces, particle‐particle interfaces and grain boundaries. Starting with indium‐magnesium‐oxide nanoparticle powders obtained via injection of an indium organic precursor into the magnesium combustion flame and subsequent particle quenching in argon, we investigated the stability of the trivalent In 3+ ions in the host lattice of MgO nanoparticles by determining grain growth, morphology evolution and impurity segregation. The latter process is initiated by vacuum annealing at 873 K and can be tracked at 1173 K on a time scale of minutes. In the first instance the surface segregated indium wets the nanoparticle interfaces. After prolonged annealing indium evaporates and leaves the powder via the gas phase. Resulting MgO nanocubes are devoid of residual indium, regain their high morphological definition and show spectroscopic fingerprints (UV Diffuse Reflectance and Photoluminescence emission) that are characteristic of electronically unperturbed MgO cube corner and edge features. The results of this combined XRD, TEM, and spectroscopy study reveal the parameter window within which control over indium segregation is used to introduce a semiconducting metal oxide component into the intergranular region between insulating MgO nanograins.

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Section: Resultssupporting

confidence: 82%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Impurity Segregation and Nanoparticle Reorganization of Indium Doped MgO Cubes

et al. 2019

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Nanoparticle Synthesis in the Gas Phase

Niedermaier¹,

Schwab²,

Diwald³

2021

Metal Oxide Nanoparticles

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Isolated Cobalt Ions Embedded in Magnesium Oxide Nanostructures: Spectroscopic Properties and Redox Activity

Schwab

Niedermaier

Zickler

et al. 2020

Chemistry A European J

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Atomic dispersion of dopants and control over their defect chemistry are central goals in the development of oxide nanoparticles for functional materials with dedicated electronic, opticalo rm agnetic properties. We produced highly dispersed oxiden anocubes with atomic distribution of cobalt ions in substitutional sites of the MgO hostl attice via metal organic chemical vapor synthesis. Vacuum annealing of the nanoparticlep owders up to 1173 Kh as no effect on the shape of the individual particles and only leads to moderate particle coarsening.S uch materialsp rocessing, however,g ives rise to the electronic reduction of particle surfaces, which-uponO 2 admission-stabilize anionic oxygenr adicals that are accessible to UV/Vis diffuse reflec-tance and electron paramagnetic resonance (EPR) spectroscopy.M ulti-reference quantum chemical calculations show that the opticalbands observed mainly originate from transitions into 4 A 2g (4 F), 4 T 1g (4 P) states with ac ontribution of transitionsi nto 2 T 1g , 2 T 2g (2 G) states through spin-orbit coupling and gain intensity through vibrational motiono ft he MgO latticeo rt he asymmetric ion field. Relatedn anostructures are ap romising materials ystem for singlea tomic site catalysis. At the same time, it represents an extremely valuable model system for the study of interfacial electron transfer processes that are key to nanoparticle chemistry and photochemistry at room temperature, and in heterogeneous catalysis.

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Iron Precursor Decomposition in the Magnesium Combustion Flame: A New Approach for the Synthesis of Particulate Metal Oxide Nanocomposites

Cited by 10 publications

References 48 publications

Impurity Segregation and Nanoparticle Reorganization of Indium Doped MgO Cubes

Impurity Segregation and Nanoparticle Reorganization of Indium Doped MgO Cubes

Nanoparticle Synthesis in the Gas Phase

Isolated Cobalt Ions Embedded in Magnesium Oxide Nanostructures: Spectroscopic Properties and Redox Activity

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