Advanced Functional Piezoelectric Materials and Applications
Published on 5. October 2022
286 pages
978-1-64490-209-7 (ISBN)
Description
The book reviews our current knowledge of piezoelectric materials, including their history, developments, properties, process design, and technical applications. Keywords: Piezoelectric Materials, Piezo-crystals, Nanogenerators, Phototronics, Piezoelectric Composites, Biomedical Applications, Energy Harvesting, Piezoelectric Thin Films, Piezoelectric Perovskites, Sensor Applications, Piezoelectric Ceramics, Piezoelectric Semiconductors, Piezoelectric Polymers.
More details
Other editions
Additional editions
Inamuddin | Tariq Altalhi | Mohammad Luqman
Advanced Functional Piezoelectric Materials and Applications
Book
10/2022
Materials Research Forum LLC
€138.80
Shipment within 10-20 days
Content
- Intro
- front-matter
- Table of Contents
- Preface
- 1
- Types, Properties and Characteristics of Piezoelectric Materials
- 1. Introduction
- 1.1 Single crystals
- 1.2 Ceramics
- 1.3 Composites
- 1.4 Polymers
- 1.5 Sensor configuration based on shape and size
- 1.6 Classification based on dimension
- 2. Properties of piezoelectric materials
- 2.1 Basic equations
- 2.2 Curie temperature
- 2.3 Phase transition
- 2.4 High dielectric constant
- 2.5 Sensitivity
- 2.6 Electromechanical Coupling Factor (k)
- 2.7 Resistivity (R) and time constant (RC)
- 2.7 Quality factors (mechanical and electrical)
- 2.8 Figure of Merit (FOM) and strain coefficient
- 2.9 Piezoelectric resonance frequency
- 2.10 Thermal expansion
- 2.11 Ageing
- 3. Characterization of piezoelectric materials
- 3.1 Measurement of piezoelectric coefficient
- 3.2 Measurement of dielectric constant
- 3.3 Measurement of Curie temperature
- 3.4 Etching and poling
- 3.5 Measurement of hysteresis (PE/SE) loops
- Conclusions
- References
- 2
- Fabrication Approaches for Piezoelectric Materials
- 1. Introduction
- 2. Preparation techniques for piezoelectric ceramics
- 2.1 Synthesis of ceramic powders
- 2.1 Solid-state reaction
- 2.2 Co-precipitation
- 2.3 Alkoxide hydrolysis
- 2.4 The sintering method
- 2.5 Templated grain growth
- 3. Piezoelectric materials in device fabrication
- 4. Bio-piezoelectric materials
- 4.1 Types bio-piezoelectric materials
- 4.2 Synthesis strategies
- 4.2.1 Thin films
- 4.2.2 Nanoplatforms
- 5. Challenges
- 5.1 Piezoelectric ceramics
- 5.2 Bio-piezoelectric materials
- Conclusion
- References
- 3
- Piezoelectric Materials-based Nanogenerators
- 1. Introduction
- 2. Piezoelectricity and crystallography
- 3. Maxwell's equations and piezoelectric nanogenerator
- 4. Piezoelectric materials for nanogenerators
- 4.1 Ceramic
- 4.1.1 Zinc oxide
- 4.1.2 Barium titanate
- 4.1.3 Lead zirconate titanate (PZT)
- 4.2 Polymer
- 4.2.1 PVDF and its copolymer
- 4.2.2 Polylactic acid
- 4.2.3 Cellulose
- 4.3 Ferroelectret
- 4.4 PVDF based composite
- 4.4.1 Ceramic filler
- 4.4.2 Carbon-based filler
- 4.4.3 Metal based filler
- 4.4.4 Other fillers
- 5. Applications of piezoelectric nanogenerator
- 5.1 Power source of electronic devices
- 5.2 Sensing application
- 6. Challenges and future scopes
- Conclusions
- Acknowledgement
- References
- 4
- Piezoelectric Materials based Phototronics
- 1. Introduction
- 1.1 Piezoelectric effect
- 1.2 Piezotronic effect
- 2. Piezo-phototronic effect
- 3. Piezoelectric semiconductor NWs
- 4. Effect on 2D materials
- 5. Effect on 3rd generation semiconductors
- 6. Piezo-phototronic effect on LED
- 7. Piezo-phototronic effect on solar cell
- 8. Piezo-phototronics in luminescence applications
- 9. Piezo-phototronics in other applications
- References
- 5
- Piezoelectric Composites and their Applications
- 1. Introduction
- 2. The mechanism of piezoelectricity and principle of PZT-polymer composites
- 3. Piezoelectric materials
- 4 Applications of piezoelectric composite materials
- 4.1 Energy harvesting applications
- 4.2 Medical applications of piezoelectric materials
- 4.2.1 Piezoelectric medical devices
- 4.2.2 Piezoelectric sensors
- 4.2.3 Piezoelectric prosthetic skin
- 4.2.4 Cochlear implants
- 4.2.5 Piezoelectric surgery
- 4.2.6 Ultrasonic dental scaling
- 4.2.7 Microdosing
- 4.2.8 Energy harvesting
- 4.2.9 Catheter applications
- 4.2.10 Neural stimulators
- 4.2.11 Healthcare monitoring
- 5. Structural health monitoring and repair
- Conclusion
- References
- 6
- Piezoelectric Materials for Biomedical and Energy Harvesting Applications
- 1. Introduction
- 1.1 Types of advance piezoelectric functional materials
- 1.1.1 Polymer piezocomposite
- 1.1.2 Ceramics piezocomposite
- 1.1.3 Polymer ceramics piezocomposite
- 2. Applications
- 2.1 Microelectromechanical system (MEMS) devices
- 2.2 MEMS generators for energy harvesting
- 2.3 MEMS sensor
- 2.3.1 Pressure sensor
- 2.3.2 Healthcare sensor
- 2.3.3 Cell and tisusse regenration
- Conclusion
- Reference
- 7
- Piezoelectric Thin Films and their Applications
- 1. Piezoelectric thin films
- 2. Lead free piezoelectric thin films
- 2.1 AlN thin films
- 2.2 ZnO thin films
- 2.2.1 Synthesis of ZnO thin films
- 2.3 KNN thin films
- 2.3.1 Synthesis of KNN thin films
- 3. Characterization techniques for piezoelectric thin film
- 3.1 Resonance spectrum method
- 3.2 Pneumatic loading method and normal loading method
- 3.3 Characterizations using capacitance measurements
- 4. Applications
- 4.1 Energy harvesting
- 4.2 Actuators
- 4.3 Electronics
- 4.4 Acoustic biosensors
- 4.5 Surface acoustic wave (SAW) biosensors
- 5. Recent developments in piezoelectric thin film devices
- Conclusion
- References
- 8
- Bulk Lead-Free Piezoelectric Perovskites and their Applications
- 1. Perovskites
- 2. Lead free perovskites
- 3. Processing of lead-free perovskites
- 4. Piezoelectricity in lead free perovskite
- 4.1 Fundamentals of piezoelectricity
- 5. Different lead-free piezoceramics and their applications
- 5.1 KNN based ceramics
- 5.2 Bismuth sodium titanate based piezoceramics and their applications
- 5.3 BaTiO3 (BT) based piezo-ceramics
- 5.3.1 BaTiO3 ceramics phase boundary
- 5.3.2 Factors in phase boundaries
- 5.3.3 Sintering and curie temperature
- 5.4 Bismuth based piezoceramics
- 5.4.1 Phase boundary in BFO-based ceramics
- 5.4.1.1 Ion substitution
- 5.4.1.2 Addition of ABO3
- 5.4.2 Temperature stability of strain properties
- 5.4.3 Relationship between piezoelectricity and phase boundaries
- 6. Requirements for piezoceramic applications
- 6.1 Actuators
- 6.2 Sensors
- 6.3 Transducers
- 6.3.1 Piezoelectric transducers
- 6.4 Resonators
- Conclusion
- References
- 9
- Piezoelectric Materials for Sensor Applications
- 1. Introduction
- 2. Piezoelectric mechanism
- 3. Types of piezoelectric materials
- 4. Fabrication methods
- 5. Applications of piezoelectric materials
- 5.1 Applications in wearable and implanted biomedical devices
- 5.2 Piezoelectric materials for energy applications
- 5.3 Piezoelectric materials in tissue engineering
- 5.4 Piezoelectric materials in other applications
- Conclusion and outlook
- References
- back-matter
- Keyword Index
- About the Editors
