Metal Halide Perovskites for Generation, Manipulation and Detection of Light
- 1st Edition - July 20, 2023
- Imprint: Elsevier
- Editors: Juan P. Martínez-Pastor, Pablo P. Boix, Guichuan Xing
- Language: English
- Paperback ISBN:9 7 8 - 0 - 3 2 3 - 9 1 6 6 1 - 5
- eBook ISBN:9 7 8 - 0 - 3 2 3 - 9 8 5 5 4 - 3
Metal Halide Perovskites for Generation, Manipulation and Detection of Light covers the current state and future prospects of lead halide perovskite photonics and photon source… Read more
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Request a sales quoteMetal Halide Perovskites for Generation, Manipulation and Detection of Light covers the current state and future prospects of lead halide perovskite photonics and photon sources, both from an academic and industrial point-of-view. Advances in metal halide perovskite photon sources (lasers) based on thin films, microcrystals and nanocrystals are comprehensively reviewed, with leading experts contributing current advances in theory, fundamental concepts, fabrication techniques, experiments and other important research innovations. This book is suitable for graduate students, researchers, scientists and engineers in academia and R&D in industry working in the disciplines of materials science and engineering.
- Includes comprehensive reviews from academic and industrial perspectives of current trends in the field of metal halide perovskite for photonics
- Provides an up-to-date look at the most recent and upcoming applications in metal halide perovskite photonics, such as; photodetectors, lighting, lasing, nonlinear photonics and quantum technologies
- Discusses future prospective trends and envisioned applications of metal halide perovskites, from near-UV to near-IR photonics
Materials Scientists and Engineers; Physicists, Physical Chemists
- Cover image
- Title page
- Table of Contents
- Copyright
- Contributors
- Section A: Metal halide perovskites for optoelectronics and photonics
- 1: Structure, composition, and stability of metal halide perovskites
- Abstract
- 1.1: Structure of metal halide perovskites
- 1.2: Electronic structure of metal halide perovskites
- 1.3: Structural stability of metal halide perovskites
- References
- 2: Intrinsic and delayed band-to-band and excitonic luminescence in metal halide perovskites
- Abstract
- 2.1: Introduction
- 2.2: The relationship between the delayed recombination of charges and slow diffusion of carriers
- 2.3: Halide vacancies as possible shallow traps
- 2.4: The participation of shallow traps in the excitation energy transfer to doping ions
- 2.5: Changes of the delayed luminescence kinetics by the nanocrystal surface treatment and aggregation
- 2.6: Conclusions
- References
- 3: First-principles modeling of the optoelectronic properties of metal halide perovskites
- Abstract
- 3.1: Introduction
- 3.2: Modeling of the excitonic effects on the optical properties
- 3.3: Electron-phonon coupling and self-exciton trapping effects on the optical properties
- 3.4: Conclusions
- References
- 4: Metal halide perovskite photodetectors
- Abstract
- Acknowledgments
- 4.1: Introduction
- 4.2: Metal-semiconductor and metal-insulator-semiconductor junctions
- 4.3: Figures of merit
- 4.4: Photoconductive detectors
- 4.5: Self-powered photovoltaic photodetectors
- 4.6: Field-effect phototransistors
- 4.7: Photodetectors based on lead-free perovskites
- 4.8: Summary and perspectives
- References
- 5: Industrial perspectives on the upscaling of perovskite materials for photovoltaic applications and its environmental impacts
- Abstract
- 5.1: Introduction
- 5.2: Growth techniques and upscaling
- 5.3: Manufacturing and industrial progress
- 5.4: Environmental impact of perovskite photovoltaic solar cells with a view on their end-of-life
- 5.5: Conclusion and outlook
- References
- Section B: Photon sources
- 6: Stimulated emission mechanisms in perovskite semiconductors
- Abstract
- 6.1: Introduction
- 6.2: Light emission and optical gain in semiconductors
- 6.3: Amplified spontaneous emission (ASE)
- 6.4: Optical gain
- 6.5: Modeling of ASE
- 6.6: Conclusions
- References
- 7: From LEDs to lasing by electrical injection, this is possible for lead halide perovskites?
- Abstract
- 7.1: Introduction
- 7.2: Light-emitting diodes (LEDs)
- 7.3: Requirements for electrical injection lasing
- 7.4: Approaches for a perovskite electrical injection lasing device
- 7.5: Summary and outlook
- References
- 8: Light-emitting field-effect transistors (LET) based on metal halide perovskites
- Abstract
- Acknowledgments
- 8.1: Introduction
- 8.2: LET architectures and operation principles
- 8.3: Perovskite LET performance optimization
- 8.4: Summary and perspectives
- References
- 9: Halide perovskite micro and nano lasers
- Abstract
- 9.1: Introduction
- 9.2: Basic photophysics in halide perovskites as gain media
- 9.3: Micro- and nanostructured perovskites lasers
- 9.4: Perovskite lasing with microexternal cavities
- 9.5: Conclusion and outlook
- References
- 10: Lead halide perovskite-based whispering gallery mode (WGM) lasers
- Abstract
- 10.1: Introduction
- 10.2: Fundamentals and optical characteristics of perovskites
- 10.3: Perovskite WGM lasers with intrinsic cavities
- 10.4: External cavities for perovskite WGM lasers
- 10.5: Summary and outlook
- References
- 11: Patterned perovskites for designing metasurfaces and laser arrays
- Abstract
- 11.1: Elucidating material properties for metal halide perovskites nanostructuring
- 11.2: Methods of halide perovskite patterning
- 11.3: Interaction of laser with halide perovskites
- 11.4: Applications of pulsed laser technologies for perovskite micro- and nanopatterning
- 11.5: Conclusion
- References
- Section C: Advanced photonic concepts
- 12: Perovskite nonlinear optical properties and photonics
- Abstract
- 12.1: Introduction
- 12.2: Basic mechanism of nonlinear optics
- 12.3: Nonlinear optical properties of organic/inorganic halide perovskite
- 12.4: Perspective of the nonlinear optical devices based on perovskite
- 12.5: Conclusions and outlook
- References
- 13: Frequency upconversion lasers using low-dimensional perovskites
- Abstract
- Acknowledgments
- 13.1: Introduction
- 13.2: Frequency upconversion ASE in low-dimensional perovskites
- 13.3: Frequency upconversion lasing in low-dimensional perovskites
- 13.4: Conclusions and outlook
- References
- 14: Polaritons and polariton condensates in perovskites
- Abstract
- 14.1: Introduction
- 14.2: Polariton—The liquid light in the cavity
- 14.3: Building blocks of polaritons in perovskites
- 14.4: Manipulations and applications of polaritons in perovskites
- References
- 15: Surface-plasmon-assisted lasing and strong exciton-photon coupling in perovskite crystals
- Abstract
- 15.1: Introduction
- 15.2: Fundamentals of surface plasmon
- 15.3: Demonstration of typical structures
- 15.4: Perovskite plasmonic laser
- 15.5: Surface-plasmon-enhanced photonic lasing
- 15.6: Strong exciton-plasmon coupling
- 15.7: Conclusions and open questions
- References
- 16: Topological photonics and vortex microlasers based on patterned perovskites
- Abstract
- 16.1: Introduction
- 16.2: Novel optical phenomena and devices based on patterned perovskites
- 16.3: Conclusion and outlook
- References
- 17: Tailoring the spontaneous emission of nanocube perovskites
- Abstract
- 17.1: Introduction
- 17.2: Perovskite nanocrystals: Synthesis, size and shape control, quantum confinement
- 17.3: Spontaneous emission by single perovskite nanocrystals
- 17.4: Engineering the rate of spontaneous emission: Purcell effect with fiber-cavity modes and Hyperbolic Metamaterials
- 17.5: Coherent spontaneous emission in perovskite supercrystals
- 17.6: Summary
- References
- 18: Photon recycling in metal halide perovskites: Its modeling and relevance to optoelectronic devices
- Abstract
- 18.1: Introduction to photon recycling in perovskites
- 18.2: Theory and modeling
- 18.3: Simulation results
- 18.4: Summary and outlook
- References
- Index
- Edition: 1
- Published: July 20, 2023
- Imprint: Elsevier
- No. of pages: 572
- Language: English
- Paperback ISBN: 9780323916615
- eBook ISBN: 9780323985543
JM
Juan P. Martínez-Pastor
Juan P. Martínez-Pastor is a Full Professor of Applied Physics at the University of Valencia, Valencia, Spain. Prof. Martínez-Pastor is an expert in Semiconductor Physics, particularly optical properties and exciton recombination dynamics in quantum wells, wires and dots based on III-V semiconductors and other compounds since 1990. Since 2006 he has led/co-led several research lines in nanoscience and nanotechnology regarding the development of several types of nanomaterials and applications to photonics and plasmonics. Since 2014 he has focused his research in optical properties, exciton recombination dynamics and applications in photonics of two-dimensional semiconductors and metal halide perovskites. He has supervised 16 PhD theses and is author/co-author of 220 peer-reviewed publications with more than 5300 citations (Google Scholar). Since 1996 he has been the principal investigator of several national and European projects, he is currently the Coordinator of DROP-IT within the FET-OPEN H2020 program. He was also promoter in 2009 of the spin-off company Intenanomat SL dedicated to the commercialization of nanoparticles.
Affiliations and expertise
Full Professor of Applied Physics, University of Valencia, Valencia, SpainPB
Pablo P. Boix
Pablo P. Boix works at the Institute of Materials Science (ICMUV), University of Valencia, Valencia, Spain. His profile combines basic education in Physics (bachelor by Universitat de València, 2008) and Nanoscience (Ph.D. by Universitat Jaume I, 2012; Master by Universitat Jaume I, 2010) with an extensive international experience developing optoelectronic devices and electrochemical characterization techniques, in both academic and industrial environments. His research interests include developing innovative materials and device configurations for optoelectronic applications, as well as unveiling their working mechanisms. He joined Nanyang Technological University (NTU, Singapore, 2012-2016) as a postdoctoral research fellow and became a group leader in perovskite optoelectronics at their early stage of the field. He contributed to pioneer advances in materials, such as the first formamidinium- based perovskite absorber and device concepts. After one year of industrial experience (Dyesol Ltd., Lausanne, Switzerland), he joined Universitat de València in 2017 with a Ramon y Cajal Fellowship. He has published more than 100 articles in peer-reviewed scientific journals (with h-index: 52) and 2 patents. He was able to participate as a “Young Scientist” at GYSS (Global Young Scientists Summit, January 2015, Singapore) and selected as Highly Cited Researcher in 2020 (Cross-Field).
Affiliations and expertise
Institute of Materials Science (ICMUV), University of Valencia, Valencia, SpainGX
Guichuan Xing
Guichuan Xing is currently an Associate Professor at the Institute of Applied Physics and Materials Engineering, University of Macau, Macau, China. Dr. Xing’s primary research interest is focused on developing and applying ultrafast nonlinear spectroscopic techniques to probing, understanding and controlling the fundamental charge and energy carrier generation, transport and relaxation in novel optoelectronic systems for energy conversion/storage and light emission applications. He has published more than 200 articles in peer-reviewed scientific journals.
Affiliations and expertise
Associate Professor, Institute of Applied Physics and Materials Engineering, University of Macau, Macau, ChinaRead Metal Halide Perovskites for Generation, Manipulation and Detection of Light on ScienceDirect