Description |
1 online resource |
Series |
Materials science and technologies |
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Materials science and technologies series.
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Contents |
Preface; Chapter 1; Processing, Microstructure, Properties, Applications and Curvature-Based Classification Schemes of Porous Ceramics; Abstract; 1. Introduction; 2. Applications of Porous Ceramics; 3. Classification Scheme for the Effective Properties of Porous Ceramics; 4. Classification of the Microstructures of Porous Ceramics; 5. Curvature as a Key Parameter of Porous Microstructures -- from Definition to Measurement; 6. Classification Scheme for the Processing Techniques of Porous Ceramics; Summary and Conclusion; Acknowledgment; References; Chapter 2 |
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Porous Ceramic and Piezocomposites: Modeling, Technology, and CharacterizationAbstract; 1. Introduction; 2. Microstructural Design Concept for Polycrystalline Composite Materials; 2.1. MSD Concept Content; 2.2. Some Examples of MSD Concept Realization; 3. Impedance Spectroscopy Characterization of Highly Attenuating Piezocomposites; 3.1. Piezoelectric Resonance Analysis Methods; 4. Porous Ferroelectric Ceramics; 4.1. Porous Piezoceramics: Porosity Origin and Microstructure; 4.2. Fabrication Methods; 4.3. Measurement Methods; 4.4. Porous Piezoceramics Modeling; 4.5. Unit Cell Models |
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4.6. Percolation Models4.7. Fractal Analysis; 4.8. Finite Element Modeling (FEM); 4.9. Experimental Data; 4.10. Full Set of Material Constants; 5. Lead Titanate and Lead Metaniobate Porous Ferroelectric Ceramics; 5.1. Porous Ceramic Preparations; 5.2. Results and Discussion; 6. Ceramic Piezocomposites Pzt/(-Al2O3; 6.1. "Damping by Scattering" Approach; 6.2. Methods of Experimental Preparation; 6.3. Method of Measurement; 6.4. Results and Discussion; 7. Dielectric, Piezoelectric and Elastic Properties of PZT/PZT Ceramic Piezocomposites; 7.1. Experimental Procedures; 7.2. Methods of Measurement |
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7.3. Results and Discussion8. Optimization of Finite Element Models for Porous Ceramic Piezoelements by Piezoelectric Resonance Analysis Method; 8.1. Method of Measurements; 8.2. FEM Calculations and Optimization Procedure; 8.3. Results and Discussion; 8.4. Full Set of Complex Material Constants; 8.5. FEM Results; 9. Simulation of Ultrasonic Wave Propagation in Non-homogeneous Anisotropic Ceramic Composites; 9.1. Experimental Scenario; 9.2. Methods of Measurements; 9.3. Simulations Algorithm; 9.4. Results and Discussion; 9.4.1. Ultrasonic Measurements |
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9.4.2. Resonance Measurements and Wave Pro SimulationsConclusion; Acknowledgments; References; Chapter 3; Superplastically Foaming Method to Make Closed Pores Inclusive Rigid Ceramics; Division of Applied Chemistry,; Graduate School of Natural Science and Technology,; Okayama University, Okayama, Japan; Absract; 1. Introduction; 2. Fabrication of Superplastacally Foamed Ceramics; 2.1. Ceramic Mono-Foam; 2.2. Gas Evolution from the Foaming Agent; 2.3. Superplastic Deformation; 2.4. Fabrication of Superplastically Porous Ceramics; 2.5. Post-Stabilization Method; 2.5.1. Experimental Procedure |
Bibliography |
Includes bibliographical references and index |
Notes |
Description based on print version record and CIP data provided by publisher |
Subject |
Porous materials.
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Ceramics -- Permeability
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TECHNOLOGY & ENGINEERING / Engineering (General)
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TECHNOLOGY & ENGINEERING / Reference
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Porous materials
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Form |
Electronic book
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Author |
Newton, Alan (Materials scientist), editor.
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LC no. |
2016035235 |
ISBN |
9781634858601 |
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1634858603 |
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