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Author Alguero, Miguel
Title Nanoscale Ferroelectrics and Multiferroics : Key Processing and Characterization Issues, and Nanoscale Effects, 2 Volumes
Imprint New York : John Wiley & Sons, Incorporated, 2016
©2015
book jacket
Edition 1st ed
Descript 1 online resource (1193 pages)
text txt rdacontent
computer c rdamedia
online resource cr rdacarrier
Note Intro -- TitlePage -- Copyright -- List of Contributors -- Preface -- Introduction: Why Nanoscale Ferroelectrics and Multiferroics? -- PART A Nanostructuring: Bulk -- 1 Incorporation Mechanism and Functional Properties of Ce-Doped BaTiO3 Ceramics Derived from Nanopowders Prepared by the Modified Pechini Method -- 1.1 Why Cerium-Doped BaTiO3? -- 1.2 Sample Preparation, Phase and Nano/Microstructural Characterization -- 1.3 Dielectric Properties -- 1.4 Raman Investigation -- 1.5 Conclusions -- Acknowledgments -- References -- 2 Synthesis and Ceramic Nanostructuring of Ferroic and Multiferroic Low-Tolerance-Factor Perovskite Oxides -- 2.1 Introduction -- 2.2 Synthesis of Perovskites Oxides -- 2.3 Processing of Ferroic and Multiferroic Materials:honey From the Ceramic Method to the Current Assisted Methods -- 2.4 Combination of Mechanosynthesis and Spark Plasma Synthesis:honey The Right Track to the Nanoscale in Ferroic Materials -- 2.5 Conclusions -- Acknowledgments -- References -- 3 Core-Shell Heterostructures:honey From Particle Synthesis to Bulk Dielectric, Ferroelectric, and Multiferroic Composite Materials -- 3.1 Introduction -- 3.2 Liquid-Phase Synthesis of Core-Shell Particles -- 3.3 BaTiO3@polymer Particles and Composites -- 3.4 Inorganic Core-Shell Particles with a Ferroelectric Core -- 3.5 Multiferroic Core-Shell Particles and Composites -- 3.6 Conclusions and Outlook -- References -- 4 Modeling of Colloidal Suspensions for the Synthesis of the Ferroelectric Oxides with Complex Chemical Composition -- 4.1 Introduction -- 4.2 Solid-State Synthesis -- 4.3 Colloidal Interactions and Aggregation -- 4.4 Aggregation in the Three-Component System -- 4.5 Applying the Modeling Results to Enhance Properties of Ferroelectric Complex Oxides -- 4.6 Conclusions and Outlook -- Acknowledgments -- References
5 Self-Assemblage and Patterning of Thin-Film Ferroic Nanostructures -- 5.1 Introduction -- 5.2 Short Survey on Classical Top-Down Approaches -- 5.3 Non-invasive Procedures -- 5.4 Embedded Ferroelectric Nanograins -- 5.5 Conclusions -- References -- 6 Thin-Film Porous Ferroic Nanostructures:honey Strategies and Characterization -- 6.1 (Nano)Microelectronics Considerations -- 6.2 Ferroics and Nanoferroic Structures -- 6.3 Meso- and Nanoporosity in Advanced Functional Materials -- 6.4 Nanoporosity in Ferroelectric Thin Films -- 6.5 Looking Ahead -- Acknowledgments -- References -- 7 Low-Temperature Photochemical Solution Deposition of Ferroelectric and Multiferroic Thin Films -- 7.1 Introduction -- 7.2 Low-Temperature Processing of Ferroelectrics and Multiferroics -- 7.3 Low Environmental Impact Precursor Chemistry -- 7.4 Aquous Solution-Gel Precursors -- 7.5 Photosensitive Sol-Gel Precursors -- 7.6 Photochemical Solution Deposition (PCSD) -- 7.7 Final Remarks -- References -- 8 Synthesis and Properties of Ferroelectric Nanotubes and Nanowires:honey A Review -- 8.1 Introduction -- 8.2 Synthesis of Ferroelectric Nanowires and Nanotubes -- 8.3 Crystal Structure, Phase Transitions, and Ferroelectric Properties -- 8.4 Applications -- 8.5 Summary and Conclusions -- References -- 9 Fabrication of One-Dimensional Ferroelectric Nano- and Microstructures by Different Spinning Techniques and Their Characterization -- 9.1 Introduction -- 9.2 Fiber Synthesis -- 9.3 Investigation of Nanostructure, Microstructure, and Phase Composition -- 9.4 Investigation of Mechanical Properties -- 9.5 Ferroelectric Characterization -- 9.6 Applications -- 9.7 Summary and Outlook -- References -- PART B: Characterization (of the Nanostructured Materials): Crystal Structure -- 10 Structural Characterization of Ferroelectric and Multiferroic Nanostructures by Advanced TEM Techniques
10.1 Introduction:honey Advanced TEM Techniques for the Analysis of Ferroelectric and Multiferroic Materials -- 10.2 Transmission Electron Microscopy -- 10.3 HAADF-STEM Structure Determination -- 10.4 Electron Energy Loss Spectroscopy -- 10.5 Future and Challenges -- References -- 11 Raman Spectroscopy of Nanostructured Ferroelectric Materials -- 11.1 Introduction -- 11.2 Raman Spectroscopy Fundamentals -- 11.3 Raman Analysis of Relaxors -- 11.4 Raman Analysis of Nanostructured Ferroelectrics -- 11.5 Tip-Enhanced Raman Spectroscopy (TERS) of Nanoscale Ferroelectrics -- 11.6 Summary -- Acknowledgments -- References -- 12 Neutron and Synchrotron X-Ray Scattering Studies of Bulk and Nanostructured Multiferroic and Ferroelectric Materials -- 12.1 Introduction -- 12.2 Synchrotron X-Ray and Neutron Facilities for Structural Characterization of Ferroelectrics and Multiferroics -- 12.3 Crystal Structure of NdMn2O5 in Powder and Single Crystalline Forms -- 12.4 Neutron Total Scattering Investigations of the BaTiO3@SiO2 Nanocomposites -- 12.5 Concluding Comments -- Acknowledgments -- References -- 13 Advanced Characterization of Multiferroic Materials by Scanning Probe Methods and Scanning Electron Microscopy -- 13.1 SPM-Related Methods in Advanced Materials Research -- 13.2 Magnetic Force Microscopy (MFM) and Related Methods -- 13.3 Electrostatic Force Microscopy (EFM) and Piezo Force Microscopy (PFM) -- 13.4 Scanning Tunneling Microscopy (STM) and Related Methods -- 13.5 Imaging of Crystallographic Orientations (SEM/EBSD) -- 13.6 New Developments in the Field of EBSD -- References -- 14 Electrostatic and Kelvin Probe Force Microscopy for Domain Imaging of Ferroic Systems -- 14.1 Introduction -- 14.2 Electrostatic Force Microscopy and Kelvin Probe Force Microscopy -- 14.3 EFM of Ferroelectric Materials -- 14.4 KPFM of Ferroelectric Materials
14.5 Recent Advances -- 14.6 Summary and Outlook -- Acknowledgments -- References -- PART C: Nanoscale Effects: Bulk Properties -- 15 Nanostructured Barium Titanate Ceramics:honey Intrinsic versus Extrinsic Size Effects -- 15.1 Introduction -- 15.2 Applications of BaTiO3 Ceramics -- Actual Demands for Passive Components -- 15.3 Size-Dependent Phenomena in Ferroelectrics -- 15.4 Size-Dependent Properties in BaTiO3 Ceramics:honey Intrinsic versus Extrinsic Size Effects -- 15.5 Conclusions -- Acknowledgments -- References -- 16 The Effects of Ceramic Nanostructuring in High-Sensitivity Piezoelectrics -- 16.1 Technological Drive for Ceramic Nanostructuring of High-Sensitivity Piezoelectrics -- 16.2 State of the Art Ferroelectric Materials for Piezoelectric Technologies -- 16.3 Nanostructuring Effects in Perovskite Systems with PZT-like MPBs -- 16.4 Nanostructuring Effects in Perovskite Systems with Intrinsic Chemical Inhomogeneity -- 16.5 Summary and Future Perspectives -- 16.6 Acknowledgments -- References -- 17 Correlation between Microstructure and Electrical Properties of Ferroelectric Relaxors -- 17.1 Introduction -- 17.2 Perovskite Relaxors -- 17.3 Aurivillius Lead-Free Ferroelectric Relaxors -- 17.4 Conclusions -- References -- 18 Local Field Engineering Approach for Tuning Dielectric and Ferroelectric Properties in Nanostructured Ferroelectrics and Composites -- 18.1 Introduction -- 18.2 Finite Element Method -- 18.3 The Role of Local Electric Field Inhomogeneity on Tunability Properties -- 18.4 Switching Properties in Inhomogeneous Ferroelectrics -- 18.5 Conclusions -- 18.6 Acknowledgments -- References -- 19 Ferroelectric Phase Transitions in Epitaxial Perovskite Films -- 19.1 Introduction -- 19.2 Experimental Study of Phase Transition -- 19.3 Dielectric Permittivity in Thin Films -- 19.4 Phase Transitions in Epitaxial Films
19.5 Concluding Remarks -- 19.6 Acknowledgments -- References -- 20 Interfaces in Epitaxial Ferroelectric Layers/Multilayers and Their Effect on the Macroscopic Electrical Properties -- 20.1 Introduction -- 20.2 Electrode Interfaces in Ferroelectric Capacitors -- 20.3 Interfaces in Complex Structures -- 20.4 Conclusions -- Acknowledgments -- References -- 21 Electric Field Control of Magnetism Based on Elastically Coupled Ferromagnetic and Ferroelectric Domains -- 21.1 Introduction -- 21.2 Domain Pattern Transfer -- 21.3 Elastic Coupling Between Magnetic and Ferroelectric Domain Walls -- 21.4 Domain Size Scaling of Pattern Transfer -- 21.5 Electric Field Control of Ferromagnetic Domains -- 21.6 Electric Field Driven Magnetic Domain Wall Motion -- 21.7 Summary and Outlook -- Acknowledgments -- References -- 22 Ferroelectric Vortices and Related Configurations -- 22.1 Insights from Simulations and Theory -- 22.2 Insights from Experiments -- Acknowledgments -- References -- 23 Reentrant Phenomena in Relaxors -- 23.1 Introduction -- 23.2 Reentrant Phases in Condensed Matter -- 23.3 Relaxor Ferroelectrics -- 23.4 Reentrant Relaxor Behavior in Ferroelectrics -- 23.5 Transverse Glassy Freezing and Canonical Relaxors -- 23.6 Reentrant Dipolar Glass State in Quantum Paraelectrics Doped with Dipolar Impurities -- 23.7 Summary and Concluding Remarks -- Acknowledgments -- References -- 24 Functional Twin Boundaries:honey Multiferroicity in Confined Spaces -- 24.1 Introduction -- 24.2 Ferroelectric Twin Boundaries -- 24.3 Conducting Twin Boundaries -- 24.4 Thermal Conductivity -- 24.5 Landau Theory of Coupled Order Parameters in Domain Walls -- 24.6 Chiral Twin Walls -- 24.7 High Wall Densities -- 24.8 Summary -- Acknowledgment -- References -- 25 Novel Approaches for Genuine Single-Phase Room Temperature Magnetoelectric Multiferroics
25.1 Introduction to Single-Phase Multiferroic Materials
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Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2020. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries
Link Print version: Alguero, Miguel Nanoscale Ferroelectrics and Multiferroics : Key Processing and Characterization Issues, and Nanoscale Effects, 2 Volumes New York : John Wiley & Sons, Incorporated,c2016 9781118935750
Subject Ferroelectric devices
Electronic books
Alt Author Gregg, J. Marty
Mitoseriu, Liliana
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