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Chemistry of nanocrystalline oxide materials : combustion synthesis, properties and applications /

Nano-oxide materials lend themselves to applications in a wide variety of emerging technological fields such as microelectronics, catalysts, ceramics, coatings, and energy storage. However, developing new routes for making nano-based materials is a challenging area for solid-state materials chemists...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Patil, K. C.
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Singapore ; London : World Scientific, ©2008.
Temas:
Acceso en línea:Texto completo
Tabla de Contenidos:
  • 1. Introduction. 1.1. General. 1.2. Preparative methods. 1.3. Scope of the book
  • 2. Combustible solid precursors to nanocrystalline oxide materials. 2.1. Introduction. 2.2. Combustible metal hydrazine and metal hydrazine carboxylate complexes. 2.3. Preparation of metal formate, acetate, oxalate, and hydrazine carboxylates. 2.4. Mixed metal oxides. 2.5. Mixed metal hydrazinium hydrazine carboxylates. 2.6. Concluding remarks
  • 3. Solution combustion synthesis of oxide materials. 3.1. Introduction. 3.2. Solution combustion synthesis (SCS). 3.3. Role of fuels. 3.4. A recipe for the synthesis of various classes of oxides. 3.5. Salient features of solution combustion method
  • 4. Alumina and related oxide materials. 4.1. Introduction. 4.2. Alumina and related oxide materials. 4.3. [symbol]-alumina. 4.4. Metal aluminates [symbol]. 4.5. Rare earth orthoaluminates [symbol]. 4.6. Garnets. 4.7. Aluminum borate. 4.8. Tialite [symbol]. 4.9. Aluminum phosphate. 4.10. Alumina composites. 4.11. Alumina nanacomposites. 4.12. Nanopigments. 4.13. Nanophosphors. 4.14. Concluding remarks
  • 5. Nano-ceria and metal-ion-substituted ceria. 5.1. Introduction. 5.2. Synthesis and properties of nano-ceria. 5.3. Synthesis of metal-ion-substituted ceria. 5.4. Characterization of metal-ion-substituted ceria. 5.5. Oxygen storage materials. 5.6. Metal-ion-substituted ceria as nanocatalysts. 5.7. Concluding remarks
  • 6. Nanocrystalline [symbol] and ferrites. 6.1. Magnetic materials. 6.2. [symbol]. 6.3. Spinel ferrites [symbol]. 6.4. Mixed metal ferrites. 6.5. Rare earth orthoferrites. 6.6. Garnets [symbol]. 6.7. Barium and strontium hexaferrites. 6.8. Concluding remarks
  • 7. Nano-titania and titanates. 7.1. Introduction. 7.2. Nano-[symbol](Anatase). 7.3. Photocatalytic properties of Nano-[symbol]. 7.4. Metal-ion-substituted [symbol]. 7.5. Titanates for nuclear waste immobilization. 7.6. Concluding remarks
  • 8. Zirconia and related oxide materials. 8.1. Introduction. 8.2. Zirconia. 8.3. Stabilized zirconia. 8.4. Nano-zirconia pigments. 8.5. [symbol] system: ZTA. 8.6. [symbol] system. 8.7. [symbol] system [symbol]. 8.8. [symbol] system: pyrochlores. 8.9. NASICONs. 8.10. Concluding remarks
  • 9. Perovskite oxide materials. 9.1. Introduction. 9.2. Dielectric materials. 9.3. Relaxor materials (PFN, PMN, PNN, and PZN). 9.4. Microwave resonator materials. 9.5. Preparation and properties of [symbol] (M = Cr, Mn, Fe, Co and Ni). 9.6. Preparation and properties of [symbol] (M = Mn and Fe). 9.7. Concluding remarks
  • 10. Nanocrystalline oxide materials for special applications. 10.1. Synthesis and properties of simple oxides. 10.2. Metal silicates. 10.3. Ceramic pigments. 10.4. [symbol]-ion-doped red phosphors. 10.5. Metal vanadates. 10.6. Rare earth metal oxides [symbol]. 10.7. Concluding remarks.