Preparation of ceramic nanoparticlesvia cellulose-assisted glycine nitrate process: a review

Birol, Hansu; Rambo, Carlos R.; Guiotoku, Marcela; Hotza, Dachamir

doi:10.1039/c2ra21810k

Cited by 35 publications

(28 citation statements)

References 109 publications

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“…In addition, the porous structure itself functions as an escape channel for the gas products, thereby avoiding the spreading out of fine powders during combustion. 24 The morphologies of the as-prepared BaFe 12 …”

Section: Resultsmentioning

confidence: 99%

Facile preparation and microwave absorption properties of porous hollow BaFe12O19/CoFe2O4 composite microrods

Huang

Zhang

Liu

et al. 2015

Journal of Alloys and Compounds

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Section: Resultsmentioning

confidence: 99%

Facile preparation and microwave absorption properties of porous hollow BaFe12O19/CoFe2O4 composite microrods

Huang

Zhang

Liu

et al. 2015

Journal of Alloys and Compounds

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“…The LST powders obtained through the above so methods have small particle size and narrow size distribution or porous structure which would enlarge the TPBs and then improve the performance. Recently, Birol et al 126 reviewed the cellulose-assisted glycine nitrate process of preparing ceramic nanoparticles. Some other so methods such as co-precipitation method, 127 sol-gel route 128 and rheological phase reaction 129,130 were the potential techniques to synthesize LST-based anode materials.…”

Section: Lst Synthesis Methodsmentioning

confidence: 99%

Progress in La-doped SrTiO₃(LST)-based anode materials for solid oxide fuel cells

et al. 2014

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Solid oxide fuel cells (SOFCs) have appeared as a promising technology for a wide variety of potential commercial applications to lessen the urgency of energy shortage and environmental pollution associated with using conventional fossil fuels. Among the worldwide SOFCs research activities, the progress of SOFCs fed with hydrocarbon fuels that contain trace amount of H 2 S is one of the most important research directions. Thereby, it becomes crucial to design novel electrode materials with enhanced catalytic activity, stability and tolerances to carbon deposition and sulfur poisoning. Lasubstituted SrTiO 3 (LST) based perovskite anodes have been widely investigated because of their high electronic conductivity in reducing atmospheres, excellent dimensional and chemical stability upon redox cycling and outstanding sulfur and coking tolerances. In this review paper, we will describe the development of LST-based anode materials for SOFCs in recent years. The synthesis, structure and fuel cell performance of the doped LST and LST-based composite anode materials are summarized in detail. The mechanism of H 2 S-induced enhancement effect for electrochemical reactions on the LST-based anode materials is explored. The challenges related to the future developments of LST-based anode materials for SOFCs are also discussed.

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“…Calcination in a furnace, or in a flame, 222)224) improves the crystallinity of the metal oxide but may leave residual carbon with possible impact on properties like the luminescence. 225),226) During this step, the reducing behavior of the biopolymer can be enhanced, a growing number of publications focuses on the formation of metal nanoparticles like Pt 227) Au, 99) or Ag 228) and metal fibers; 30) see also the case of Mn(VII).…”

Section: Metal Oxide@egg Whitementioning

confidence: 99%

“…Glossary BP: Biopolymer; PS: polysaccharide; MO: metal oxide; MMO: mixed metal oxide; NP: nanoparticles; SSA: specific surface area; PVD: plasma vapour deposition; ALD: atomic layer deposition; LIB Lithium-ion battery. For mixed material like composite or core shell materials, the A@B is used and mean that A is quantitatively the minor phase and B the major phase, example TiO 2 @C is mostly carbon covered or mixed with TiO 2 Related reviews: Related to this field of researches, we propose to the reader the following review with the corresponding key words: biotemplating, 29) ceramic nano-powders from cottoncellulose, 30)32) evolution of cellulose under thermal treatment, 33) biopolymer as binder of ceramic powder for the sintering and monolith formation (starch, 34) cellulose 35) gelatin 36) ).…”

Section: Introductionmentioning

confidence: 99%

Hybrid metal oxide@biopolymer materials precursors of metal oxides and metal oxide-carbon composites

Plumejeau

Alauzun

Boury

2015

J. Ceram. Soc. Japan

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Metal oxide can be prepared by mineralization process of biopolymers like cellulose, starch, alginate, chitosan, chitin, carrageenan, dextran, DNA, pectin, collagen, gelatin, silk, lignin and white-egg. The formation of corresponding hybrid composite [metal oxide@biopolymer] allows mastering the morphology, porosity, composition and structure of metal oxide and also gives access to [metal oxide@carbon] composite upon carbonization of the biopolymer We briefly review the recent advances in this fields in order to show the diversity of the approaches and their adaptations to produce material with potential applications in catalysis, energy and environment.

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Preparation of ceramic nanoparticlesvia cellulose-assisted glycine nitrate process: a review

Cited by 35 publications

References 109 publications

Facile preparation and microwave absorption properties of porous hollow BaFe12O19/CoFe2O4 composite microrods

Facile preparation and microwave absorption properties of porous hollow BaFe12O19/CoFe2O4 composite microrods

Progress in La-doped SrTiO₃(LST)-based anode materials for solid oxide fuel cells

Hybrid metal oxide@biopolymer materials precursors of metal oxides and metal oxide-carbon composites

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Preparation of ceramic nanoparticlesvia cellulose-assisted glycine nitrate process: a review

Cited by 35 publications

References 109 publications

Facile preparation and microwave absorption properties of porous hollow BaFe12O19/CoFe2O4 composite microrods

Facile preparation and microwave absorption properties of porous hollow BaFe12O19/CoFe2O4 composite microrods

Progress in La-doped SrTiO3(LST)-based anode materials for solid oxide fuel cells

Hybrid metal oxide@biopolymer materials precursors of metal oxides and metal oxide-carbon composites

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Product

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Progress in La-doped SrTiO₃(LST)-based anode materials for solid oxide fuel cells