Reductive/expansion synthesis of zero valent submicron and nanometal particles

Zea, Hugo; Luhrs, Claudia; Phillips, Jonathan

doi:10.1557/jmr.2010.66

Cited by 14 publications

(19 citation statements)

References 54 publications

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“…Transferring the mixed paste of aluminum nitrate and urea from room temperature to a preheated oven involves an extremely fats heating of the mixture, leading to a thermal decomposition of the mixture in a temperature range between 160 to 250 o C, depending of the paste composition [7,12,13,15,16]. Aluminum nitrate decomposition has been reported to start at temperatures as low as 150 o C [15], meanwhile urea decomposes in a first stage between 180 -250 o C to form ammonium and isocianic acid followed by a further decomposition of the isocianic acid to a gaseous mixture of ammonium and carbon dioxide at temperatures above 350 o C [10,12]. In the case of the aluminum nitrate, the initial stage of decomposition below 170 o C, comprises a series of simultaneous reactions such as dehydration, hydrolysis, and destruction of nitrate groups sharing comparable reaction mechanism to processes such as dehydroxylation of hydroxy salts, that also could be formed during the thermal decomposition of hydrolytic processes that take place at temperatures above 170 o C. Therefore, stoichiometric and thermodynamics conditions of the mix at the initial moment of decomposition may lead to the formation of an initial hydroxyl compound of the type Alx(OH)y(NO3), the nitrate molecules decomposes rapidly due to the thermodynamic favorable reaction to the formation of ammonium in the presence of urea.…”

Section: Resultsmentioning

confidence: 99%

“…The study of simple methods for the production of particulate oxides with high thermal resistance like alumina and alumina based ceramics oxides has aroused great interest recently; in particular, aluminum oxides are of great interest given their important physical characteristics such as high hardness, high stability, high insulation, and transparency. An interesting alternative for the production of metallic particles was proposed by Zea et al [10], involving economic reagents and using simple equipment; this versatile reductive/expansion synthesis (RES) approach not only allows the generation of metallic material but also by tuning the reaction atmosphere allows the formation of oxides. Under this approach (M-RES, modified reductive/expansion synthesis), an initial reductive condition coupled with an oxidant atmosphere and thermal treatment generates aluminum oxides with different crystallographic phases.…”

Section: Introductionmentioning

confidence: 99%

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Evaluation of the modified reduction/expansion synthesis in the production of nanoparticulate alumina

Zea¹

2017

ces

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This study aims to probe the feasibility of a modified reduction/expansion synthesis (M-RES) to generate alumina nanoparticles from nitrate precursors. 1/1 weight ratio mixtures of aluminum nitrate and urea exposed to fast heating at three temperatures (350, 650, 950 °C, under oxidize atmosphere), in order to create the kinetic and thermodynamic conditions to promote chemical reactions and phase transformations leading to the formation of alumina nanoparticles. Crystallographic, morphological and textural properties were evaluated via X-ray diffraction, scanning electron microscopy and nitrogen adsorptions isotherms. Xray revealed little crystallographic development at 350 o C (composed mainly of pseudo boehmite); samples synthesized at 650 and 950 o C presented a welldeveloped crystallographic structure (delta alumina and gamma alumina, respectively). SEM pictures show the transition from amorphous micron aggregates from the 350 o C sample to a more faceted structure material, characteristic of highly crystalline alumina, at 950 o C. M-RES procedure generates powder material with low total surface area and pore volume. Synthesis temperature showed a direct correlation with the development of total surface area and volume pore, the highest values were obtained for the 950 o C synthesized sample (29.5 m 2 /g and 1698 x 10-2 mL/g), while the 350 o C temperature generated the lowest values (4.9 m 2 /g and 3,142 x 10-3 mL/g). M-RES procedure proved to be a suitable procedure to obtain oxidized nanoparticles of sizes ranging from 50 to 200 nm. The M-RES technical simplicity could become a scalable and efficient process for the synthesis of nanoparticles.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Evaluation of the modified reduction/expansion synthesis in the production of nanoparticulate alumina

Zea¹

2017

ces

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“…Estudios anteriores demostraron que la técnica denominada síntesis de reducción expansiva (RES por su sigla en inglés Reduction Expansive Synthesis) genera aglomerados micrométricos fácilmente disgregables de nanopartículas metálicas (Zea et al 2011. Estos resultados mostraron que partículas cero valentes se pueden producir a partir de sales nitrogenadas del metal de interés, por medio de la descomposición súbita de urea.…”

Section: Discussionunclassified

“…Inicialmente el nitrato se descompone en óxido (en ausencia de urea) como es el caso de la síntesis por combustión; cuando las mezclas urea/ nitrato se someten a un calentamiento rápido hay una "convolución" de los procesos de descomposición. De esta forma, la urea se descompone generando gases reductores que permiten la formación del metal más que del óxido (Zea et al 2011). Adicionalmente, la creación de partículas metálicas micro y submicrométricas a partir de precursores de óxido e hidróxido, indican que el uso de precursores óxidos para la completa reducción a micro-partículas, requiere mayor contenido de urea y mayores temperaturas; mientras que con el uso de hidróxidos se logra la reducción a temperaturas más bajas (Luhrs et al 2013).…”

Section: Introductionunclassified

Modificación del proceso de reducción expansiva para la síntesis de nanopartículas de hierro

Rodríguez

Zea²

2014

Univ. Sci.

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The reductive expansion method has been used successfully in the synthesis of metal nanoparticles. However, there are no reports regarding the use of expansion methods to produce oxidized nanoparticles. Here, we propose an adjustment to the current oxidizing atmosphere application during reductive expansion. Mixtures of different weight ratios of iron nitrogen salts and urea (blowing agent) were subjected to thermal shock in an oven; the sudden sublimation of the urea and nitrogen salts originated a fine dispersion of material that came into contact with reducing gases. During this sublimation, metallic iron nanoparticles were produced and subsequently oxidized by the prevailing oxidizing atmosphere. Through characterization using X-ray diffraction, we determined that the crystalline phase of the formed nanoparticles depends on the composition of the reactants. In contrast, particle size distribution, surface area and oil absorption are not strongly influenced by this composition.

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“…With these data, temperatures and transition or reaction enthalpies can be obtained. Some recommendations for the operation of the DSC are the following [5]. In this work we determined the thermal properties of the ionic system xAgI-(1-x)NH4I by Differential Scanning Calorimetry.…”

Section: Introductionmentioning

confidence: 99%

Determination of thermal properties of the ionic system xAgI-(1-x)NH4I by differential scanning calorimetry

Canate-Gonzalez¹,

Fong-Silva²,

Severiche-Sierra³

et al. 2018

ces

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The research focuses on the search for more experimental evidence of the thermal, electrical behavior of the family MI-AgI (where M = NH4), which results when NH4 + is exchanged for Ag + in the binary system xAgI-(1-x)NH4I as a study model with concentrations of x = 0.4, 0.5.0.6, 0.7.0.8 and 0.9. The thermal properties were identified by the Differential Scanning Calorimetry (DSC) technique. For this system in each of the concentrations, there is evidence of a decrease in temperature to the quality that occurs in the transition from poor phase conductor called β / γ to highly conductive called α compared with that of pure Agi that is given in 420 K (147 ºC).

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Reductive/expansion synthesis of zero valent submicron and nanometal particles

Abstract: Abstract

Cited by 14 publications

References 54 publications

Evaluation of the modified reduction/expansion synthesis in the production of nanoparticulate alumina

Evaluation of the modified reduction/expansion synthesis in the production of nanoparticulate alumina

Modificación del proceso de reducción expansiva para la síntesis de nanopartículas de hierro

Determination of thermal properties of the ionic system xAgI-(1-x)NH4I by differential scanning calorimetry

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