Advances in lead-free piezoelectric materials. (2018)
- Record Type:
- Book
- Title:
- Advances in lead-free piezoelectric materials. (2018)
- Main Title:
- Advances in lead-free piezoelectric materials
- Further Information:
- Note: Jiagang Wu.
- Authors:
- Wu, Jiagang
- Contents:
- Intro; Foreword; Contents; 1 Historical Introduction; Abstract; 1.1 Piezoelectric Effect; 1.2 Dominant Factors to Piezoelectric Effect; 1.2.1 Phase Transitions; 1.2.1.1 Lead-Based Materials; 1.2.1.2 Lead-Free Materials; 1.2.2 Microstructure; 1.2.2.1 Grain Morphology Versus Electrical Properties; 1.2.2.2 Domain Structure Versus Electrical Properties; 1.2.3 Poling Behavior; 1.2.3.1 Traditional Poling Methods; 1.2.3.2 New Poling Method; 1.3 Why to Choose Lead-Free Piezoelectrics; 1.4 Summarization of Development of Lead-Free Piezoelectrics; References; 2 Preparation and Characterization. Abstract2.1 Preparation Techniques; 2.1.1 Ceramics; 2.1.2 Textured Method; 2.1.3 Nanostructure; 2.1.4 Thin Films; 2.1.4.1 Physical Methods; 2.1.4.2 Chemical Methods; 2.1.5 Single Crystal; 2.2 Characterization Methods; 2.2.1 Crystal Structure; 2.2.2 Observation of Domain Structure; 2.2.3 Electrical Properties; References; 3 Alkali Niobate-Based Piezoelectric Materials; Abstract; 3.1 Introduction; 3.2 Category; 3.3 Structure and Phase Boundaries; 3.3.1 Structure; 3.3.2 Orthorhombic-Tetragonal Phase Boundaries; 3.3.3 Rhombohedral-Orthorhombic Phase Boundary; 3.4 New Phase Boundaries. 3.4.1 Design Idea3.4.2 Giant Piezoelectricity (d33 greaterthan 400 pC/N) Versus Compositions; 3.4.3 High Piezoelectricity Versus High Curie Temperature; 3.5 High Piezoelectricity Versus Temperature Stability; 3.5.1 95K0.40Na0.60NbO3-0.05Bi0.5Ag0.5HfO3; 3.6 Physical Origin for Enhanced Electrical Properties; 3.6.1Intro; Foreword; Contents; 1 Historical Introduction; Abstract; 1.1 Piezoelectric Effect; 1.2 Dominant Factors to Piezoelectric Effect; 1.2.1 Phase Transitions; 1.2.1.1 Lead-Based Materials; 1.2.1.2 Lead-Free Materials; 1.2.2 Microstructure; 1.2.2.1 Grain Morphology Versus Electrical Properties; 1.2.2.2 Domain Structure Versus Electrical Properties; 1.2.3 Poling Behavior; 1.2.3.1 Traditional Poling Methods; 1.2.3.2 New Poling Method; 1.3 Why to Choose Lead-Free Piezoelectrics; 1.4 Summarization of Development of Lead-Free Piezoelectrics; References; 2 Preparation and Characterization. Abstract2.1 Preparation Techniques; 2.1.1 Ceramics; 2.1.2 Textured Method; 2.1.3 Nanostructure; 2.1.4 Thin Films; 2.1.4.1 Physical Methods; 2.1.4.2 Chemical Methods; 2.1.5 Single Crystal; 2.2 Characterization Methods; 2.2.1 Crystal Structure; 2.2.2 Observation of Domain Structure; 2.2.3 Electrical Properties; References; 3 Alkali Niobate-Based Piezoelectric Materials; Abstract; 3.1 Introduction; 3.2 Category; 3.3 Structure and Phase Boundaries; 3.3.1 Structure; 3.3.2 Orthorhombic-Tetragonal Phase Boundaries; 3.3.3 Rhombohedral-Orthorhombic Phase Boundary; 3.4 New Phase Boundaries. 3.4.1 Design Idea3.4.2 Giant Piezoelectricity (d33 greaterthan 400 pC/N) Versus Compositions; 3.4.3 High Piezoelectricity Versus High Curie Temperature; 3.5 High Piezoelectricity Versus Temperature Stability; 3.5.1 95K0.40Na0.60NbO3-0.05Bi0.5Ag0.5HfO3; 3.6 Physical Origin for Enhanced Electrical Properties; 3.6.1 Identification of Phase Boundaries; 3.6.2 Ferroelectric Domains; 3.6.2.1 Width of Ferroelectric Domains Versus Piezoelectricity; 3.6.2.2 Domain Structure Versus Piezoelectricity; 3.7 Challenges and Solutions of Temperature Stability; 3.7.1 KNN-Based Ceramics. 3.7.1.1 Contradiction Between Piezoelectricity and Temperature Stability3.7.1.2 Methods to Improve Both Piezoelectricity and Temperature Stability; 3.7.2 KNN-Based Single Crystal; 3.8 Conclusion; References; 4 Bi0.5Na0.5TiO3-Based Piezoelectric Materials; Abstract; 4.1 Introduction; 4.2 Composition Design and Property's Adjustment; 4.2.1 Ion Substitution; 4.2.2 Binary System; 4.2.3 Ternary Systems; 4.2.4 The Addition of Oxides; 4.3 Electric Field-Induced Phase Transition; 4.4 Strain Behavior; 4.4.1 Giant Strain Accompanying with Large Driving Field; 4.4.2 Large Strain Under Low Driving Field. 4.4.3 Typical Samples for Giant Strain4.4.4 Physical Origin for Giant Strain; 4.4.4.1 Giant Strain from Filed-Induced Relaxor to Ferroelectric Phase Transition; 4.4.4.2 Complementary Mechanisms for the Ultrahigh Strain; 4.5 New Effects; 4.5.1 Energy Storage; 4.5.2 Electrocaloric Effect; 4.6 Phase Boundary Versus Electrical Properties; 4.7 Conclusion; References; 5 BaTiO3-Based Piezoelectric Materials; Abstract; 5.1 Introduction; 5.2 Pure BaTiO3 Material; 5.3 Approaches to Modulate Electrical Properties; 5.3.1 (Ba, Ca)(Ti, Zr)O3; 5.3.2 (Ba, Ca)(Ti, Sn)O3; 5.3.3 (Ba, Ca)(Ti, Hf)O3. … (more)
- Publisher Details:
- Singapore : Springer
- Publication Date:
- 2018
- Extent:
- 1 online resource
- Subjects:
- 621.3815
Piezoelectric materials
Lead-free electronics manufacturing processes
TECHNOLOGY & ENGINEERING -- Mechanical
Lead-free electronics manufacturing processes
Piezoelectric materials
Optical and Electronic Materials
Inorganic Chemistry
Energy Harvesting
Surface and Interface Science, Thin Films
Environmental Health
Electronic books - Languages:
- English
- ISBNs:
- 9789811089985
9811089981
9789811089992 - Related ISBNs:
- 9789811089978
9811089973
981108999X - Notes:
- Note: Includes bibliographical references.
Note: Online resource; title from PDF title page (SpringerLink, viewed August 27, 2018). - Access Rights:
- Legal Deposit; Only available on premises controlled by the deposit library and to one user at any one time; The Legal Deposit Libraries (Non-Print Works) Regulations (UK).
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- Restricted: Printing from this resource is governed by The Legal Deposit Libraries (Non-Print Works) Regulations (UK) and UK copyright law currently in force.
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- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library HMNTS - ELD.DS.407326
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