04538nam 22007935 450 991091378580332120251113183707.09789819790180981979018210.1007/978-981-97-9018-0(MiAaPQ)EBC31808138(Au-PeEL)EBL31808138(CKB)36725635100041(DE-He213)978-981-97-9018-0(OCoLC)1477220275(EXLCZ)993672563510004120241201d2024 u| 0engurcnu||||||||txtrdacontentcrdamediacrrdacarrierDefects Engineering in Electroceramics for Energy Applications /edited by Upendra Kumar1st ed. 2024.Singapore :Springer Nature Singapore :Imprint: Springer,2024.1 online resource (518 pages)Engineering Materials,1868-12129789819790173 9819790174 Fundamentals of Solid-State Physics -- Defects in Electroceramics -- PREPARATION OF CERAMICS: DIFFERENT APPROACHES.-Emerging Strategies for Electroceramic Preparation: Contemporary Methods and Novel Techniques -- Foundations of Ceramic Synthesis: Processes, Principles, and Potential Biomedical Prospects -- Thin film preparation of Electroceramics -- FUNDAMENTAL CHARACTERIZATION TECHNIQUES: IMPEDANCE AND MODULUS SPECTROSCOPY -- Defect Engineering for Tailoring Thermoelectric Properties of Electroceramics -- Role of Electroceramics in Renewable Energy Technologies -- Structural Perspective on Multifunctional Oxide Materials -- Bioactive glass for biomedical application: an overview -- Bulk Metallic Glasses: Effect of Various Temperatures with Nature of Constituent elements in Zr-Al/Ti-Ni-Cu BMGs -- Microwave Dielectric Properties of Electroceramics -- Microwave dielectric resonator antenna using electroceramics- A Perspective -- Electroceramics-based materials for sensor technology -- Piezoelectric, Pyroelectric, and Dielectric Properties of PZT: Nylon 11 and Graphite Doped PZT: Nylon11 Composites -- Pyroelectric Properties of Electroceramics -- HEXAFERRITE COMPOSITE-BASED MATERIALS: POTENTIAL APPLICATIONS -- FUTURE PERSPECTIVES OF ELECTROCERAMICS.This book highlights the history of electroceramics starting from synthesis using different routes of the solid solution to hybrid nanocomposites and its applications in different renewable energy, thermistor, actuators, thermoelectric, thermo-optic, sensor, and much more applications in electronic industry. In ceramic materials, the properties are controlled by doping and composition, but the grain size and the porosity of the sintered ceramics also play essential roles. The latter features depend on the method of fabrication. The end-user requirements define the optimum physical and chemical properties of ceramic materials. Therefore, the design and fabrication of ceramic components are multidisciplinary, spanning physical chemistry, metallurgy, and chemical engineering. Also included in this book are the various characterizing techniques to study the physical properties of ceramics.Engineering Materials,1868-1212Condensed matterCeramic materialsMaterialsCatalysisForce and energySolid state chemistrySurfaces (Physics)PhysicsCondensed Matter PhysicsCeramicsMaterials for Energy and CatalysisSolid-State ChemistrySurface and Interface and Thin FilmApplied and Technical PhysicsCondensed matter.Ceramic materials.Materials.Catalysis.Force and energy.Solid state chemistry.Surfaces (Physics)Physics.Condensed Matter Physics.Ceramics.Materials for Energy and Catalysis.Solid-State Chemistry.Surface and Interface and Thin Film.Applied and Technical Physics.530.41Upēndra Kumār1887825MiAaPQMiAaPQMiAaPQBOOK9910913785803321Defects Engineering in Electroceramics for Energy Applications4526784UNINA