Novel Material Properties Based on Flame-synthesized Nanomaterials

The principles of high-temperature reactive particle formation in flames are characterized by a sequence of partly interacting rate processes in the gas flow, while the necessary energy is delivered by the exothermic combustion reaction heatin...

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Main Author: Hartmut Wiggers
Format: Article
Language:English
Published: Hosokawa Powder Technology Foundation 2014-03-01
Series:KONA Powder and Particle Journal
Subjects:
tco
Online Access:https://www.jstage.jst.go.jp/article/kona/27/0/27_2009017/_pdf/-char/en
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spelling doaj-33aff4efd061423d9fed35eaea1f7c482021-02-03T00:58:52ZengHosokawa Powder Technology FoundationKONA Powder and Particle Journal0288-45342187-55372014-03-0127018619410.14356/kona.2009017konaNovel Material Properties Based on Flame-synthesized NanomaterialsHartmut Wiggers0Institut für Verbrennung und Gasdynamik, University Duisburg-EssenThe principles of high-temperature reactive particle formation in flames are characterized by a sequence of partly interacting rate processes in the gas flow, while the necessary energy is delivered by the exothermic combustion reaction heating the flow to high temperatures. A complete description of the precursor decomposition kinetics and the subsequent oxidation/hydrolysis reactions is rarely obtained, while the properties of the products manufactured such as size, morphology, phase composition, and crystallography are decisively influenced by these parameters. A precise understanding and control of the initial steps is therefore required to open up the possibility of tuning particle properties.In the present study, the formation of oxidic particles in flame reactors is presented. It will be shown that the stoichiometry and crystallography of oxides such as ZnO, SnO2 and TiO2, and therefore their physical and chemical properties, can be adjusted depending on the reaction conditions. In addition to the synthesis of pure materials, coated particles as well as nanocomposites are accessible when a few requirements are fulfilled. In the case of immiscible oxides such as TiO2 and SiO2, composites consisting of separate phases are produced, while the formation of composites from miscible compounds usually requires a two-step process that tends to produce poorly mixed materials. Nevertheless, in the case of kinetically controlled synthesis, a one-step formation of nanocomposites from miscible oxides can be realized when the kinetics of precursor decomposition and particle formation of the participating oxides are quite different. This results in materials that exhibit new properties according to the used oxides. As an example, the one-step formation of homogeneously dispersed superparamagnetic Fe2O3 in fumed silica will be shown. Chemically, this material behaves like common silica but due to the superparamagnetic characteristics of the embedded iron oxide, it can be heated in a contactless manner by means of an alternating magnetic field. Applications focusing on contactless hardening and bonding become apparent.https://www.jstage.jst.go.jp/article/kona/27/0/27_2009017/_pdf/-char/enflame synthesisnanoparticlestconanocompositessuperparamagnetic fe2o3magsilica®
collection DOAJ
language English
format Article
sources DOAJ
author Hartmut Wiggers
spellingShingle Hartmut Wiggers
Novel Material Properties Based on Flame-synthesized Nanomaterials
KONA Powder and Particle Journal
flame synthesis
nanoparticles
tco
nanocomposites
superparamagnetic fe2o3
magsilica®
author_facet Hartmut Wiggers
author_sort Hartmut Wiggers
title Novel Material Properties Based on Flame-synthesized Nanomaterials
title_short Novel Material Properties Based on Flame-synthesized Nanomaterials
title_full Novel Material Properties Based on Flame-synthesized Nanomaterials
title_fullStr Novel Material Properties Based on Flame-synthesized Nanomaterials
title_full_unstemmed Novel Material Properties Based on Flame-synthesized Nanomaterials
title_sort novel material properties based on flame-synthesized nanomaterials
publisher Hosokawa Powder Technology Foundation
series KONA Powder and Particle Journal
issn 0288-4534
2187-5537
publishDate 2014-03-01
description The principles of high-temperature reactive particle formation in flames are characterized by a sequence of partly interacting rate processes in the gas flow, while the necessary energy is delivered by the exothermic combustion reaction heating the flow to high temperatures. A complete description of the precursor decomposition kinetics and the subsequent oxidation/hydrolysis reactions is rarely obtained, while the properties of the products manufactured such as size, morphology, phase composition, and crystallography are decisively influenced by these parameters. A precise understanding and control of the initial steps is therefore required to open up the possibility of tuning particle properties.In the present study, the formation of oxidic particles in flame reactors is presented. It will be shown that the stoichiometry and crystallography of oxides such as ZnO, SnO2 and TiO2, and therefore their physical and chemical properties, can be adjusted depending on the reaction conditions. In addition to the synthesis of pure materials, coated particles as well as nanocomposites are accessible when a few requirements are fulfilled. In the case of immiscible oxides such as TiO2 and SiO2, composites consisting of separate phases are produced, while the formation of composites from miscible compounds usually requires a two-step process that tends to produce poorly mixed materials. Nevertheless, in the case of kinetically controlled synthesis, a one-step formation of nanocomposites from miscible oxides can be realized when the kinetics of precursor decomposition and particle formation of the participating oxides are quite different. This results in materials that exhibit new properties according to the used oxides. As an example, the one-step formation of homogeneously dispersed superparamagnetic Fe2O3 in fumed silica will be shown. Chemically, this material behaves like common silica but due to the superparamagnetic characteristics of the embedded iron oxide, it can be heated in a contactless manner by means of an alternating magnetic field. Applications focusing on contactless hardening and bonding become apparent.
topic flame synthesis
nanoparticles
tco
nanocomposites
superparamagnetic fe2o3
magsilica®
url https://www.jstage.jst.go.jp/article/kona/27/0/27_2009017/_pdf/-char/en
work_keys_str_mv AT hartmutwiggers novelmaterialpropertiesbasedonflamesynthesizednanomaterials
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