Preparation of BaTiO3 nanopowders by the solution combustion method

Khort, Alexander; Podbolotov, K. B.

doi:10.1016/j.ceramint.2016.06.178

Cited by 17 publications

(8 citation statements)

References 24 publications

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“…Solution combustion synthesis (SCS) has been successfully applied to the preparation of diverse nanomaterials, e.g., binary and complex metal oxide nanomaterials [21,22], nano-crystalline metallic materials [23] and nanocomposites [24,25]. SCS is a time-saving and energy-saving method, especially for the synthesis of complex oxides which can be easily adapted for scale-up applications [26].…”

Section: Introductionmentioning

confidence: 99%

Facile synthesis of atomically mixed Fe 50 Co 50 nanoalloys via a simple combustion-based route

Zhang

Qin

Liu

et al. 2017

Journal of Alloys and Compounds

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Section: Introductionmentioning

confidence: 99%

Facile synthesis of atomically mixed Fe 50 Co 50 nanoalloys via a simple combustion-based route

Zhang

Qin

Liu

et al. 2017

Journal of Alloys and Compounds

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“…Due to this feature, combustion of SCS precursors occurs even in inert atmospheres and in vacuum and result in high-quality NMs with homogeneous crystal phases. The method has previously been used to produce NMs of different functional classes, including pure and multicomponent metal NMs [34][35][36][37] , as well as simple and complex oxides [38][39][40] . Since SCS is one of few techniques that could easily be scaled-up for industrial production of a broad class of NMs, it is important to study particle properties as well as corrosion and dissolution characteristics of SCS NPs in e.g.…”

Section: Introductionmentioning

confidence: 99%

Corrosion and Transformation of Solution Combustion Synthesized Co, Ni and CoNi Nanoparticles in Synthetic Freshwater with and without Natural Organic Matter

Khort

Hedberg

Mei

et al. 2020

Preprint

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Pure metallic Co, Ni, and their bimetallic compositions of Co3Ni, CoNi, and CoNi3 nanomaterials were prepared by solution combustion synthesis. Microstructure, phase composition, and crystalline structure of these nanoparticles (NPs) were characterized along with studies of their corrosion and dissolution properties in synthetic freshwater with and without natural organic matter (NOM). The nanomaterials consisted of aggregates of fine NPs (3–30 nm) of almost pure metallic and bimetallic crystal phases with thin surface oxide covered by a thin carbon shell. The nanomaterials were characterized by BET surface areas ranging from ~ 1 to 8 m2/g for the Ni and Co NPs, to 22.93 m2/g, 14.86 m2/g, and 10.53 m2/g for the Co3Ni, CoNi, CoNi3 NPs, respectively. More Co and Ni were released from the bimetallic NPs compared with the pure metals although their corrosion current densities were lower. In contrast to findings for the pure metal NPs, the presence of NOM increased the release of Co and Ni from the bimetallic NPs in freshwater compared to freshwater only even though its presence reduced the corrosion rate (current density). It was shown that the properties of the bimetallic nanomaterials were influenced by multiple factors such as their composition, including carbon shell, type of surface oxides, and the entropy of mixing.

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“…“Bottom‐up” strategies via solution‐based routes have been in focus since they offer relatively better compositional and morphological control than the solid‐state reaction, which yields hard‐agglomerated powders with chemical inhomogeneity and undesirable morphology that has broadly dispersed particle sizes . Various solution techniques such as simple reflux, co‐precipitation via oxalate and citrate routes, solution combustion, and hydrothermal, solvotherma and sol‐gel processes have been explored. Co‐precipitation is easier than other solution methods, which can produce the crystalline BaZrO 3 phase at temperatures mostly lower than 500°C.…”

Section: Introductionmentioning

confidence: 99%

“…The use of urea or glycine as a reducing agent in combustion solution permits a single‐step synthesis that initiates the BaZrO 3 phase. Unfortunately, the calcination process is still required for completing the crystalline phase that generally provides an irregular morphology with large micron‐sized particle products . Desirable shape and size of the BaZrO 3 particle could be achieved directly from the direct reaction of precursor ions in strong basic solution via hydrothermal and solvothermal methods .…”

Section: Introductionmentioning

confidence: 99%

“…Unfortunately, the calcination process is still required for completing the crystalline phase that generally provides an irregular morphology with large micron-sized particle products. 16,17 Desirable shape and size of the BaZrO 3 particle could be achieved directly from the direct reaction of precursor ions in strong basic solution via hydrothermal and solvothermal methods. 18 However, more uniform particles were developed by using complex organic ligands in order to prevent particle agglomeration in the solvothermal method.…”

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confidence: 99%

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The modification of surface, size and shape of barium zirconate powder via salt flux

2019

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The “top‐down” process via direct conversion of the micro (μm)‐to‐submicroscale (sub‐μm) particle was applied in this work by using eutectic chloride salts to prepare BaZrO3. The particle size at optimum condition could be decreased by more than 10 times from 2.1 ± 0.9 μm to 168 ± 23 nm without destroying the 1:1 of Ba:Zr stoichiometry. The uniform sub‐μm‐BaZrO3 powder was sintered in order to obtain ~98% dense ceramic at 1400°C/10 h, which is significantly lower than the 1650°C in normal cases. The microwave dielectric constant, tan δ, and quality factor were also determined. Furthermore, this method also was applied to lead‐free piezoelectric material in the 0.87BaTiO3–0.13BaZrO3–CaTiO3 (0.87BT–0.13BZ–CT) system. The particle size of 0.87BT–0.13BZ–CT was reduced greatly from >10 µm to 2.8 ± 0.4 µm. It can be proved that salt flux dissolution method enables high‐purity with uniform sub‐micro/nanometer powder production in one step by using simple laboratory equipment and low‐cost raw materials.

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Preparation of BaTiO3 nanopowders by the solution combustion method

Cited by 17 publications

References 24 publications

Facile synthesis of atomically mixed Fe 50 Co 50 nanoalloys via a simple combustion-based route

Facile synthesis of atomically mixed Fe 50 Co 50 nanoalloys via a simple combustion-based route

Corrosion and Transformation of Solution Combustion Synthesized Co, Ni and CoNi Nanoparticles in Synthetic Freshwater with and without Natural Organic Matter

The modification of surface, size and shape of barium zirconate powder via salt flux

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