Ferroelectric materials for energy applications / edited by Haitao Huang and James F. Scott

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Resource type: Ressourcentyp: Buch (Online)Book (Online)Language: English Publisher: Weinheim : Wiley-VCH, 2018Description: 1 Online-Ressource (372 Seiten)ISBN:

9783527807499
9783527807505
3527807500
9783527807475
3527807470
9783527342716

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Genre/Form:

Aufsatzsammlung

Additional physical formats: 9783527342716 | Erscheint auch als: Ferroelectric materials for energy applications. Durck-Ausgabe. Weinheim, Germany : Wiley-VCH, 2018. xi, 372 SeitenDDC classification:

621.3

RVK: RVK: UP 4700Local classification: Lokale Notation: elt 9.2LOC classification:

TK7872.F44

DOI: DOI: 10.1002/9783527807505Online resources:

Zugang im Netz des KIT

Summary: 61; Akash Bhatnagar 3.1 Introduction 61 3.2 Historical Background 62 3.2.1 Recent Studies 68 3.3 Modulation of the Effect 74 3.3.1 Polarization 74 3.3.2 Electrodes 77 3.3.3 Band Gap Engineering 79 3.3.4 Photo-mechanical Coupling 84 3.4 Summary and Outlook 88 References 89 4 Organic–Inorganic Hybrid Perovskites for Solar Energy Conversion 95; Peng You and Feng Yan 4.1 Introduction 95 4.2 Fundamental Properties of Hybrid Perovskites 96 4.2.1 Crystal Structures 96 4.2.2 Optical Properties 97 4.2.3 Charge Transport Properties 98 4.2.4 Compositional Engineering and Bandgap Tuning 98 4.3 Synthesis of Hybrid Perovskite Crystals 99 4.3.1 Bulk Crystal Growth 99 4.3.2 Nanocrystal Synthesis 100 4.4 Deposition Methods of Perovskite Films 101 4.4.1 One-Step Solution Process 101 4.4.2 Two-Step SolutionSummary: And Jun-Wei Zha 6.1 Introduction 169 6.2 Energy StorageTheory 170 6.3 Energy Storage of Ferroelectric Polymers 172 6.4 Energy Storage of Ferroelectric Polymer-Based Nanocomposites 175 6.4.1 Ferroelectric Polymer-Based Nanocomposites Using 0D Nanofillers 177 6.4.1.1 Surface-Modified 0D Nanofillers 177 6.4.1.2 Core–Shell Structure 0D Nanofillers 181 6.4.1.3 Multilevel Structure Nanocomposites 183 6.4.2 Ferroelectric Polymer-Based Nanocomposites Using 1D Nanofillers 184 6.4.2.1 Surface-Modified 1D Nanofillers 184 6.4.2.2 Core–Shell Structure 1D Nanofillers 189 6.4.2.3 Multilevel Structure Nanocomposites 189 6.4.3 Ferroelectric Polymer-Based Nanocomposites Using 2D Nanofillers 190 6.5 Summary 193 References 193 7 Pyroelectric Energy Harvesting: Materials and Applications 203; Chris R. Bowen, Mengying Xie, Yan Zhang, Vitaly YuSummary: And Applications Concerned with Radiations 219 7.8 Conclusions 221 Acknowledgments 222 References 222 8 Ferroelectrics in Electrocaloric Cooling 231; Biaolin Peng and Qi Zhang 8.1 Fundamentals of Electrocaloric Effects 231 8.1.1 Maxwell Relations and Coupled Electrocaloric EffecSummary: Kong, Haitao Huang, and Sean Li 1.1 Introduction 1 1.2 Piezoelectric Mechanical Energy Harvesting 4 1.2.1 Piezoelectricity 4 1.2.2 Brief History of Modern Piezoelectric Ceramics 6 1.2.3 Principle of Piezoelectric Effect for Mechanical Energy Harvesting 7 1.3 PyroelectricThermal Energy Harvesting 10 1.3.1 Principle of Pyroelectric Effect 10 1.3.2 Pyroelectric Coefficient and Electrocaloric Coefficient 12 1.3.3 Primary and Secondary Pyroelectric Coefficient 14 1.3.4 Tertiary Pyroelectric Coefficient and Other Aspects 15 1.3.5 Pyroelectric Effect versus Phase Transition 17 1.4 Electrocaloric (EC) Effect of Ferroelectric Materials 19 1.5 Ferroelectric Photovoltaic Solar Energy Harvesting 23 1.6 Concluding Remarks 27 References 28 2 Piezoelectric Energy Generation 33; Hong GSummary: Lead-Containing Glass-ceramic 146 5.5.2.2 BaTiO3-Based Glass-ceramic 146 5.5.2.3 Nb-Containing Glass-ceramic 147 5.5.3 Interface Effect-Related Energy-Storage Performance 148 5.6 Energy-Storage Performance in Relaxor Ferroelectrics 151 5.6.1 PLZT Relaxor Ferroelectrics 152 5.6.2 BaTiO3-Based Relaxor Ferroelectrics 154 5.6.3 PbTiO3-Based Relaxor Ferroelectrics 157 5.6.4 BiFeO3-Based Relaxor Ferroelectrics 157 5.7 The General Future Prospects 158 References 159 6 Ferroelectric PolymerMaterials for Electric Energy Storage 169; Zhi-Min Dang, Ming-Sheng ZhengSummary: Process 102 4.4.3 Vapor-Phase Deposition 103 4.5 Efficiency Roadmap of Perovskite Solar Cells 103 4.6 Working Mechanism and Device Architectures of Perovskite Solar Cells 106 4.7 Key Challenges of Perovskite Solar Cells 108 4.7.1 Long-Term Stability 108 4.7.2 I–V Hysteresis 110 4.7.3 Toxicity of Raw Materials 111 4.8 Summary and Perspectives 111 References 112 5 Dielectric Ceramics and Films for Electrical Energy Storage 119; Xihong Hao 5.1 Introduction 119 5.2 Principles of Dielectric Capacitors for Electrical Energy Storage 120 5.2.1 The Basic Knowledge on Capacitors 120 5.2.2 Some Important Parameters for Electrical Energy Storage 122 5.2.2.1 Energy-Storage Density 122 5.2.2.2 Energy Efficiency 122 5.2.2.3 Breakdown Strength (BDS) 123 5.2.2.4 Thermal Stability 124 5.2.2.5 Power Density 125 5.2.2.6 Service Life 125Summary: Preface xi 1 Fundamentals of Ferroelectric Materials 1; Ling BPPN: PPN: 104868590XPackage identifier: Produktsigel: ZDB-35-UBC | ZDB-35-WIC

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