
Perovskite Metal Oxides
Synthesis, Properties, and Applications
- 1st Edition - May 30, 2023
- Editors: Srikanta Moharana, Tanmaya Badapanda, Santosh Kumar Satpathy, Ram Naresh Mahaling, Rajneesh Kumar
- Language: English
- Paperback ISBN:9 7 8 - 0 - 3 2 3 - 9 9 5 2 9 - 0
- eBook ISBN:9 7 8 - 0 - 3 2 3 - 9 9 5 3 0 - 6
Perovskite Metal Oxides: Synthesis, Properties and Applications provides an overview on the topic, including the synthesis of various types of perovskites, their propertie… Read more

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Request a sales quotePerovskite Metal Oxides: Synthesis, Properties and Applications provides an overview on the topic, including the synthesis of various types of perovskites, their properties, characterization and application. The book reviews the applications of this category of materials for photovoltaics, electronics, biomedical, fuel cell, photocatalyst, sensor, energy storage and catalysis, along with processing techniques of perovskite metal oxides with a focus on low-cost and high-efficiency methods, including various properties and probable applications in academia and industry. Other sections discuss strategies to improve the functionality of perovskite metal oxide materials, including chemical methods and controlling the size, shape and structure of the materials.
Finally, applications of perovskite metal oxides in energy conversion and storage, sensing and electronics are covered.
- Provides an overview of perovskite metal oxides, with an emphasis on synthesis, fabrication and characterization methods
- Discusses strategies to improve the functionality of perovskite metal oxide materials, including chemical methods and controlling the size, shape and structure of the materials
- Reviews applications of perovskite metal oxides in energy conversion and storage, sensing and electronics
- Cover
- Title page
- Table of Contents
- Front Matter
- Copyright
- Contributors
- Series editor biography
- Preface to the series
- Part One: Introduction to perovskite metal oxides
- 1: Concepts and recent advancements in perovskite metal oxides
- Abstract
- 1.1: Introduction
- 1.2: Perovskite metal oxide
- 1.3: Structure–property relationship and role of tolerance factor
- 1.4: Applications of perovskite-phase metal oxide materials
- 1.5: Summary and future prospects
- References
- 2: Metal oxide perovskites: Structure and properties
- Abstract
- 2.1: Introduction
- 2.2: Crystal structure of perovskites
- 2.3: Different forms of perovskite structures
- 2.4: Properties of perovskites
- 2.5: Summary
- References
- 3: An overview and recent progress of single and double perovskite metal oxides
- Abstract
- 3.1: Introduction
- 3.2: Perovskite structure: A chameleon to material science
- 3.3: Double perovskites
- 3.4: Size effect and stability
- 3.5: Transition-metal oxides
- 3.6: Synthesis method
- 3.7: Applications
- 3.8: Recent achievements in applications
- 3.9: Prospects and challenges
- 3.10: Limitations
- 3.11: Conclusions
- References
- 4: Nonstoichiometric perovskites and derivatives
- Abstract
- 4.1: Introduction
- 4.2: Barium titanate
- 4.3: Applications of nonstoichiometric BT compounds
- 4.4: Various synthesis techniques of BT compounds
- 4.5: Effects of nonstoichiometry on BT compounds
- 4.6: Conclusions
- References
- 5: Nonmetal oxide perovskite-based materials (carbon-based perovskites and halide-based perovskites)
- Abstract
- Conflict of interest
- 5.1: Introduction
- 5.2: Structure of nonmetal perovskite materials
- 5.3: Properties of perovskite materials
- 5.4: Nonmetal carbon-based perovskite materials
- 5.5: Nonmetal halide-based perovskite materials
- 5.6: Synthesis of perovskite materials
- 5.7: Applications of perovskite materials
- 5.8: Conclusions and future perspectives
- References
- Part Two: Synthesis and characterization of metal oxide perovskites
- 6: Conventional approaches to synthesis and deposition of perovskite metal oxides
- Abstract
- 6.1: Introduction
- 6.2: Conventional perovskite metal oxide ceramics processing
- 6.3: Solid-state synthesis of perovskite metal oxide
- 6.4: General method of preparation of perovskite metal oxide nanoceramics
- 6.5: High-energy ball milling methods for the synthesis of perovskite metal oxide
- 6.6: Sol-gel synthesis of perovskite metal oxide
- 6.7: Chemical solution deposition method of perovskite metal oxides
- 6.8: Hydrothermal synthesis of perovskite metal oxide
- 6.9: Electrospinning of perovskite metal oxide
- 6.10: Flame-based techniques for the synthesis of perovskite metal oxide
- 6.11: Solvothermal reaction method of perovskite metal oxides
- 6.12: Conclusion and perspectives
- References
- 7: Synthesis and characterization of perovskite-based QDs, 1D, 2D, and hierarchical nanomaterials
- Abstract
- 7.1: Introduction
- 7.2: Perovskite nanomaterials
- 7.3: Literature
- 7.4: Motivations
- 7.5: Synthesis methods of perovskite nanomaterials
- 7.6: Characterizations of perovskite nanomaterials
- 7.7: Conclusions
- 7.8: Future prospective
- References
- Part Three: Perovskite-based composites and their characterization
- 8: Perovskite metal oxide-based composite materials: Potential candidates for electronics and optoelectronics
- Abstract
- 8.1: Introduction
- 8.2: Crystal structure
- 8.3: Applications of MOPs
- 8.4: Summary and outlook
- References
- 9: Barium zirconate—A simple perovskite with multidimensional applications
- Abstract
- 9.1: Introduction to barium zirconate
- 9.2: A review on different techniques for synthesis of barium zirconate
- 9.3: Barium zirconate as a proton conducting electrolyte for solid oxide fuel cell
- 9.4: Microwave dielectric properties and applications
- 9.5: Photophysical properties of barium zirconate
- 9.6: Conclusion
- References
- 10: Effect of rare-earth elements on perovskite composite materials
- Abstract
- 10.1: General introduction: Origin and history of perovskites
- 10.2: Perovskites: Structure, stability, and classification
- 10.3: Synthesis methods
- 10.4: Effect of rare-earth doping on the host perovskite
- 10.5: Applications: Past, present, and future
- References
- 11: Tuning of physical and chemical properties of perovskite ceramic materials through surface modifications
- Abstract
- 11.1: Introduction
- 11.2: Experimental details
- 11.3: Effect of surface hydroxylation on composite film
- 11.4: Conclusions and future trends
- References
- 12: Perovskite-type dielectric ceramic-based polymer composites for energy storage applications
- Abstract
- Conflict of interest statement
- 12.1: Introduction
- 12.2: Ceramic materials
- 12.3: Modulation of dielectric and electrical properties of BFO
- 12.4: Energy storage performance in perovskite-type dielectric ceramics
- 12.5: Summary
- References
- Part Four: Applications of perovskites
- 13: Electronic applications of perovskite
- Abstract
- 13.1: General introduction
- 13.2: Transition metal oxide
- 13.3: Ferroelectrics and related materials
- 13.4: Phase transition
- 13.5: Diffuse phase transition (DPT)
- 13.6: Classification of ferroelectric oxides
- 13.7: Perovskite structure
- 13.8: Properties of perovskite oxides
- 13.9: Electronic application
- 13.10: Conclusions
- References
- 14: Energy storage applications of perovskites
- Abstract
- 14.1: Introduction
- 14.2: Classifications based on functionalities and their governing properties
- 14.3: Dielectric capacitors
- 14.4: Electrochemical capacitors
- 14.5: Batteries
- 14.6: Conclusion
- References
- 15: Biomedical applications of perovskite-based materials
- Abstract
- Acknowledgments
- 15.1: Introduction
- 15.2: Perovskite-based materials and devices for biomedical imaging
- 15.3: Applications of perovskite nanoparticles in biology
- 15.4: Perovskite-based electrochemical biosensors
- 15.5: Conclusions
- References
- 16: Perovskites for fuel cell applications
- Abstract
- 16.1: Introduction
- 16.2: Perovskite as a cathode in SOFC
- 16.3: Perovskite as an anode in SOFC
- 16.4: Perovskite as electrolyte in SOFC
- 16.5: Perovskite as interconnects for SOFC
- 16.6: Perovskites in PEMFC
- 16.7: Synthesis and processing of perovskites
- 16.8: Conclusions
- References
- 17: Perovskite material for photocatalysis
- Abstract
- Acknowledgment
- 17.1: Introduction
- 17.2: Perovskite material
- 17.3: Mechanism of photocatalysis
- 17.4: Properties of perovskite materials
- 17.5: Application of perovskite materials
- 17.6: Current status and future perspectives
- References
- Further reading
- 18: Perovskites in photoelectrochemical water splitting
- Abstract
- 18.1: Introduction
- 18.2: Fundamentals of photoelectrochemical water splitting
- 18.3: Perovskite oxide materials for photoelectrochemical water splitting
- 18.4: Approaches to employ perovskite for photoelectrochemical water splitting
- 18.5: Literature review of perovskite materials for photoelectrochemical water splitting
- 18.6: Summary and perspectives
- 18.7: Conclusion
- 18.8: Future challenges
- References
- 19: Application of perovskites in solar cells
- Abstract
- 19.1: Introduction
- 19.2: Perovskites and their suitability in solar cells
- 19.3: Hybrid organic–inorganic PSCs
- 19.4: Inorganic PSCs
- 19.5: Conclusions
- References
- 20: Perovskite-based LEDs and lasers
- Abstract
- 20.1: Introduction
- 20.2: Perovskite materials for light emission
- 20.3: Light-emitting devices
- 20.4: Stability of perovskite material sampling
- 20.5: Stability of perovskite LEDs
- 20.6: Perspective: Electrically pumped perovskite lasers
- 20.7: Inorganic perovskite based laser’s devices
- 20.8: Conclusion
- References
- 21: Perovskite-based electrochemical sensing of ion and gas molecules: An overview
- Abstract
- 21.1: Introduction
- 21.2: Metal ions, gases, and their toxic effects
- 21.3: Perovskite structure
- 21.4: Sensing mechanism
- 21.5: Perovskite for gas and ion sensors
- 21.6: Gas sensing parameters
- 21.7: Future perspectives on perovskite-based sensors
- 21.8: Conclusion
- References
- 22: Perovskite in catalysis and electrocatalysis
- Abstract
- 22.1: Introduction
- 22.2: Perovskite structure and properties
- 22.3: Catalytic properties of perovskite materials
- 22.4: Electrocatalytic properties of perovskite materials
- 22.5: Conclusion
- References
- 23: Ferroelectric perovskite thin films as nonvolatile computer memories
- Abstract
- 23.1: Introduction
- 23.2: Ferroelectricity in perovskite oxides
- 23.3: Important parameters in ferroelectric thin films
- 23.4: Material selection for memory application
- 23.5: Synthesis of perovskite ferroelectric thin film
- 23.6: Stability of the thin films
- 23.7: Working of ferroelectric piezoelectric thin films as nonvolatile computer memories
- 23.8: Summary
- References
- 24: Ferroelectric perovskites as electro-optic switching devices, modulators and optical memory
- Abstract
- 24.1: Introduction
- 24.2: Perovskite crystal structure and ferroelectricity
- 24.3: Spontaneous electric polarization
- 24.4: Origin of electric field-induced strain behavior
- 24.5: Electro-optic effect
- 24.6: Transparent electro-optic perovskites
- 24.7: Optical switches
- 24.8: Electro-optic modulators
- 24.9: Optical memory
- 24.10: Conclusions and future perspectives
- References
- 25: Development of less toxic perovskite materials for solar cell applications
- Abstract
- 25.1: Introduction
- 25.2: Material structure
- 25.3: Pb-based halide perovskites materials
- 25.4: Current status of lead-free perovskites for solar cell applications
- 25.5: Conclusions and future prospects
- References
- 26: Perovskite-based light detectors (pyrodetectors)
- Abstract
- 26.1: Introduction
- 26.2: Fundamentals of light detectors
- 26.3: Light detection and characterization
- 26.4: Operating principles
- 26.5: Fabrication process and material specifications
- 26.6: Conclusions
- References
- Index
- No. of pages: 728
- Language: English
- Edition: 1
- Published: May 30, 2023
- Imprint: Elsevier
- Paperback ISBN: 9780323995290
- eBook ISBN: 9780323995306
SM
Srikanta Moharana
Dr. Srikanta Moharana is an Assistant Professor at the Department of Chemistry, School of Applied Sciences, Centurion University of Technology and Management, Odisha, India. He obtained his Ph.D. and M.Phil. degrees in Chemistry from the School of Chemistry, Sambalpur University, India. He has received his M.Sc. degree in Chemistry from National Institute of Technology, Rourkela. He was awarded Prof. GB Behera Best PhD thesis award under the banner of Orissa chemical society, India. His research experience as well as research interests, lies in graphene, carbon nanotubes and ceramic based polymer nanocomposites synthesis and Characterization for advanced energy storage applications. He is a life member of Orissa Chemical Society.
TB
Tanmaya Badapanda
SS
Santosh Kumar Satpathy
Santosh Kumar Satpathy is an Assistant Professor in the Department of Physics at Centurion University of Technology and Management, Odisha, India. His areas of research are ferroelectrics, advanced ceramic materials, multiferroics, polymers, ceramic composites, and other ceramic materials for the application of perovskite materials.
RM
Ram Naresh Mahaling
RK