Gas-phase flame synthesis and properties of magnetic iron oxide nanoparticles with reduced oxidation state

Kumfer, Benjamin M.; Shinoda, Kōzō; Jeyadevan, Balachandran; Kennedy, Ian M.

doi:10.1016/j.jaerosci.2010.01.003

Cited by 82 publications

(66 citation statements)

References 39 publications

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“…[12]. Оксиды железа присут-�-16 указывается в работе [12]. Оксиды железа присут--16 указывается в работе [12].…”

Section: таблицаunclassified

“…Оксиды железа присут-�-16 указывается в работе [12]. Оксиды железа присут--16 указывается в работе [12]. Оксиды железа присут-ствуют в виде гетита Таким образом, совершенно очевидно существенное отличие фазового состава ТССА, полученных при сварке металлов электродами АНО-4 и ЦЛ-11.…”

Section: таблицаunclassified

“…Вопрос применения твердой составляющей сварочного аэрозоля в качестве катализатора низкотемпературного разложения озона впервые освещен в работе [7]. Из анализа литературных данных [8][9][10][11][12][13] следует, что химический и фазовый состав ТССА зависит от режима сварки, природы свариваемого металла и электродов. Последние, как правило, отличаются химическим составом проволоки и покрытия.…”

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Physicochemical Properties of the Solid Component of Welding Aerosol. I. Phase Composition

Rakitskaya¹,

Truba²,

Ennan³

et al. 2015

Odesa National University Herald. Chemistry

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“…[12]. Оксиды железа присут-�-16 указывается в работе [12]. Оксиды железа присут--16 указывается в работе [12].…”

Section: таблицаunclassified

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Physicochemical Properties of the Solid Component of Welding Aerosol. I. Phase Composition

Rakitskaya¹,

Truba²,

Ennan³

et al. 2015

Odesa National University Herald. Chemistry

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“…Moreover, these nanoparticles offer many potential applications namely, catalytic materials, waste water treatment adsorbents, pigments, gas sensors, ion exchangers, coatings, magnetic data storage devices [28][29][30][31]. Table 3 summarizes the former papers on the control size of iron oxide particles by adjusting the precursor types and precursor concentration in different spray pyrolysis process, respectively [32][33][34][35][36]. As seen different types of iron compounds such as Fe(CO)5, Fe(NO3)3, FeSO4, FeCl3 are suitable for the production of iron oxide particles in the spray pyrolysis method.…”

Section: Introductionmentioning

confidence: 99%

Orta frekans indüksiyon yöntemi ile nano-metal ve nano-metal oksit partikül sentezinin incelenmesi

Kartal¹,

Kiliç²,

Sireli³

et al. 2016

SAUFenBilDer

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Synthesis of Ag, Fe2O3 and TiO2 was investigated in medium frequency induction system to determine ideal conditions for the particle production with desired size. A high frequency ultrasonic generator was attached to induction furnace to synthesize particles from solutions of AgNO3, FeCl3, titanium tetra iso-propoxide (TTIP). Experiments were carried out under concentrations of 0.1 M, 0.01 M at constant parameters; 15 min. time, 800 ºC temperature, 1.0 L/min. flow rate. X-ray diffraction (XRD) studies confirmed the particle formation without contamination. Scanning electron microscopy (SEM) examinations revealed that size of particles were in the range of 50 nm to 400 nm.Keywords: nanoparticle, titanium dioxide, iron oxide, silver, medium frequency induction Orta frekans indüksiyon yöntemi ile nano-metal ve nano-metal oksit partikül sentezinin incelenmesi ÖZ Bu çalışmada, gümüş (Ag), demir oksit (Fe2O3) ve titanyum dioksit (TiO2) partiküllerinin nano-boyutta üretimleri için gerekli şartlar, orta frekanslı indüksiyon partikül üretim sisteminde incelenmiştir. Partikül üretim sistemi; orta frekanslı indüksiyon fırını ile yüksek frekans ultrasonik atomizerin birleştirilmesi ile oluşturulmuştur. Bahsi geçen nanopartiküllerin üretimi 0,1 M ve 0,01 M konsantrasyonların da AgNO3, FeCl3.6H2O, Titanyum tetra izopropoksit (TTIP) başlangıç malzemeleri kullanılarak gerçekleştirilmiştir. Deneyler, sabit 800 ºC reaksiyon sıcaklığı, 1.0 L/dk. taşıyıcı gaz debisi ve 15 dk. deney süresi şartlarında yapılmıştır. XRD ve SEM kullanılarak karakterize edilen nanopartiküllerin safsızlık içermediği ve 50 nm ile 400 nm arasında değişen boyutlarda oldukları görülmüştür.

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“…Since the end of the late 1980s, several gas phase synthesis methods are used for the synthesis of materials, especially matter in form of powders and nanoparticles [1][2][3][4][5][6][7][8][9][10][11][12]. The common feature of all gas phase methods is that they use vaporized chemical compounds or precursors, which undergo a chemical reaction in a gaseous environment.…”

Section: Introductionmentioning

confidence: 99%

Microwave Plasma Synthesis of Materials—From Physics and Chemistry to Nanoparticles: A Materials Scientist’s Viewpoint

Szabó

Schlabach

2014

Inorganics

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Abstract:In this review, microwave plasma gas-phase synthesis of inorganic materials and material groups is discussed from the application-oriented perspective of a materials scientist: why and how microwave plasmas are applied for the synthesis of materials? First, key players in this research field will be identified, and a brief overview on publication history on this topic is given. The fundamental basics, necessary to understand the processes ongoing in particle synthesis-one of the main applications of microwave plasma processes-and the influence of the relevant experimental parameters on the resulting particles and their properties will be addressed. The benefit of using microwave plasma instead of conventional gas phase processes with respect to chemical reactivity and crystallite nucleation will be reviewed. The criteria, how to choose an appropriate precursor to synthesize a specific material with an intended application is discussed. A tabular overview on all type of materials synthesized in microwave plasmas and other plasma methods will be given, including relevant citations. Finally, property examples of three groups of nanomaterials synthesized with microwave plasma methods, bare Fe 2 O 3 nanoparticles, different core/shell ceramic/organic shell nanoparticles, and Sn-based nanocomposites, will be described exemplarily, comprising perspectives of applications.

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Gas-phase flame synthesis and properties of magnetic iron oxide nanoparticles with reduced oxidation state

Cited by 82 publications

References 39 publications

Physicochemical Properties of the Solid Component of Welding Aerosol. I. Phase Composition

Physicochemical Properties of the Solid Component of Welding Aerosol. I. Phase Composition

Orta frekans indüksiyon yöntemi ile nano-metal ve nano-metal oksit partikül sentezinin incelenmesi

Microwave Plasma Synthesis of Materials—From Physics and Chemistry to Nanoparticles: A Materials Scientist’s Viewpoint

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