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Optoelectronic Organic-Inorganic Semiconductor Heterojunctions
summarizes advances in the development of organic-inorganic
semiconductor heterojunctions, points out challenges and possible
solutions for material/device design, and evaluates prospects for
commercial applications. Introduces the concept and basic mechanism
of semiconductor heterojunctions Describes a series of
organic-inorganic semiconductor heterojunctions with desirable
electrical and optical properties for optoelectronic devices
Discusses typical devices such as solar cells, photo-detectors, and
optoelectronic memories Outlines the materials and device
challenges as well as possible strategies to promote the commercial
translation of semiconductor heterojunctions-based optoelectronic
devices Aimed at graduate students and researchers working in
solid-state materials and electronics, this book offers a
comprehensive yet accessible view of the state of the art and
future directions.
This book addresses perovskite quantum dots, discussing their
unique properties, synthesis, and applications in nanoscale
optoelectronic and photonic devices, as well as the challenges and
possible solutions in the context of device design and the
prospects for commercial applications. It particularly focuses on
the luminescent properties, which differ from those of the
corresponding quantum dots materials, such as multicolor emission,
fluorescence narrowing, and tunable and switchable emissions from
doped nanostructures. The book first describes the characterization
and fabrication of perovskite quantum dots. It also provides
detailed methods for analyzing the electrical and optical
properties, and demonstrates promising applications of perovskite
quantum dots. Furthermore, it presents a series of optoelectronic
and photonic devices based on functional perovskite quantum dots,
and explains the incorporation of perovskite quantum dots in
semiconductor devices and their effect of the performance. It also
explores the challenges related to optoelectronic devices, as well
as possible strategies to promote their commercialization. As such,
this book is a valuable resource for graduate students and
researchers in the field of solid-state materials and electronics
wanting to gain a better understanding of the characteristics of
quantum dots, and the fundamental optoelectronic properties and
operation mechanisms of the latest perovskite quantum dot-based
devices.
This book addresses perovskite quantum dots, discussing their
unique properties, synthesis, and applications in nanoscale
optoelectronic and photonic devices, as well as the challenges and
possible solutions in the context of device design and the
prospects for commercial applications. It particularly focuses on
the luminescent properties, which differ from those of the
corresponding quantum dots materials, such as multicolor emission,
fluorescence narrowing, and tunable and switchable emissions from
doped nanostructures. The book first describes the characterization
and fabrication of perovskite quantum dots. It also provides
detailed methods for analyzing the electrical and optical
properties, and demonstrates promising applications of perovskite
quantum dots. Furthermore, it presents a series of optoelectronic
and photonic devices based on functional perovskite quantum dots,
and explains the incorporation of perovskite quantum dots in
semiconductor devices and their effect of the performance. It also
explores the challenges related to optoelectronic devices, as well
as possible strategies to promote their commercialization. As such,
this book is a valuable resource for graduate students and
researchers in the field of solid-state materials and electronics
wanting to gain a better understanding of the characteristics of
quantum dots, and the fundamental optoelectronic properties and
operation mechanisms of the latest perovskite quantum dot-based
devices.
Advanced memory technologies are impacting the information era,
representing a vibrant research area of huge electronic industry
interest. The demand for data storage, computing performance and
energy efficiency is increasing exponentially and will exceed the
capabilities of current information technologies. Alternatives to
traditional silicon technology and novel memory principles are
expected to meet the need of modern data-intensive applications
such as “big data” and artificial intelligence (AI). Functional
materials or methodologies may find a key role in building novel,
high speed and low power consumption computing and data storage
systems. This book covers functional materials and devices in the
data storage areas, alongside electronic devices with new
possibilities for future computing, from neuromorphic next
generation AI to in-memory computing. Summarizing different memory
materials and devices to emphasize the future applications,
graduate students and researchers can systematically learn and
understand the design, materials characteristics, device operation
principles, specialized device applications and mechanisms of the
latest reported memory materials and devices.
Functional Tactile Sensors: Materials, Devices and Integrations
focuses on the subject of novel materials design and device
integration of tactile sensors for functional applications. The
book addresses the design, materials characteristics, device
operation principles, specialized device application and mechanisms
of the latest reported tactile sensors. The emphasis of the book
lies in the materials science aspects of tactile
sensors-understanding the relationship between material properties
and device performance. It will be an ideal resource for
researchers working in materials science, engineering and physics.
Ambipolar materials represent a class of materials where positive
and negative charge carriers can both transport concurrently. In
recent years, a diverse range of materials have been synthesized
and utilized for implementing ambipolar charge transport, with
applications in high-density data storage, field effect
transistors, nanotransitors, photonic memory, biomaterial-based
memories and artificial synapses. This book highlights recent
development of ambipolar materials involving materials design,
fundamental principles, interface modifications, device structures,
ambipolar characteristics and promising applications. Challenges
and prospects for investigating ambipolar materials in electronics
and optoelectronics are also discussed. With contributions from
global leaders in the field, this title will appeal to graduate
students and researchers who want to understand the design,
materials characteristics, device operation principles, specialized
device application and mechanisms of the latest ambipolar
materials.
Photo-Electroactive Non-Volatile Memories for Data Storage and
Neuromorphic Computing summarizes advances in the development of
photo-electroactive memories and neuromorphic computing systems,
suggests possible solutions to the challenges of device design, and
evaluates the prospects for commercial applications. Sections
covers developments in electro-photoactive memory, and photonic
neuromorphic and in-memory computing, including discussions on
design concepts, operation principles and basic storage mechanism
of optoelectronic memory devices, potential materials from organic
molecules, semiconductor quantum dots to two-dimensional materials
with desirable electrical and optical properties, device
challenges, and possible strategies. This comprehensive, accessible
and up-to-date book will be of particular interest to graduate
students and researchers in solid-state electronics. It is an
invaluable systematic introduction to the memory characteristics,
operation principles and storage mechanisms of the latest reported
electro-photoactive memory devices.
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