Nanoscale Compound Semiconductors and their Optoelectronics Applications

Nanoscale Compound Semiconductors and their Optoelectronics Applications is a book that discusses the basic and fundamental properties of nanoscale compound semiconductors and their role in modern technological products, including their optical properties, size-dependent properties, and tunable properties. It also discusses the role of compound semiconductors in the advancement of energy-efficient optoelectronics and solar cell devices and their photocatalytic property by doping with graphene oxides.

Format: Paperback / softback
Length: 458 pages
Publication date: 24 January 2022
Publisher: Elsevier Science Publishing Co Inc

Nanoscale Compound Semiconductors and their Optoelectronics Applications delves into the comprehensive understanding of nanoscale compound semiconductors and their pivotal role in contemporary technological advancements. This comprehensive resource explores the fundamental properties of these materials, shedding light on their optical, size-dependent, and tunable characteristics. It provides a thorough review of key methods employed in their synthesis and characterization, emphasizing their significance in advancing energy-efficient optoelectronics and solar cell devices. Additionally, the book delves into the photocatalytic property of these materials by incorporating graphene oxides, offering a promising and emerging pathway for diverse applications. By unraveling the intricacies of nanoscale compound semiconductors, this book serves as a valuable resource for researchers, engineers, and students in the fields of materials science, electronics, and renewable energy.
Nanoscale compound semiconductors, with their remarkable properties, have emerged as key components in modern technological products. These materials, characterized by their small size, exhibit unique optical, size-dependent, and tunable characteristics, making them highly valuable in various applications. In this comprehensive book, we delve into the fundamental properties of nanoscale compound semiconductors, including their optical properties, size-dependent properties, and tunable properties. We explore key methods employed in their synthesis and characterization, emphasizing their significance in advancing energy-efficient optoelectronics and solar cell devices. Additionally, we discuss the photocatalytic property of these materials by incorporating graphene oxides, offering a promising and emerging pathway for diverse applications. By unraveling the intricacies of nanoscale compound semiconductors, this book serves as a valuable resource for researchers, engineers, and students in the fields of materials science, electronics, and renewable energy.

The optical properties of nanoscale compound semiconductors are of paramount importance in their applications. These materials exhibit a wide range of optical phenomena, such as absorption, emission, and scattering, which can be tailored by controlling their composition and structure. For instance, semiconductors with narrow bandgaps, such as gallium arsenide (GaAs), can be used for high-efficiency solar cells, while semiconductors with large bandgaps, such as silicon (Si), can be used for light-emitting diodes (LEDs). The size-dependent properties of nanoscale compound semiconductors also play a significant role in their applications. As the size of these materials decreases, their electrical and optical properties undergo significant changes, leading to new phenomena such as quantum confinement and surface-enhanced Raman scattering. This size-dependent behavior allows for the development of miniaturized electronic and optical devices with enhanced performance.

Tunable properties of nanoscale compound semiconductors are another key aspect that contributes to their versatility. These materials can be engineered to exhibit different optical properties by varying their composition and structure. For example, doping with different elements can change the bandgap of a semiconductor, allowing it to absorb or emit light at different wavelengths. This property enables the development of color-tunable displays, sensors, and photodetectors. Moreover, the tunable properties of nanoscale compound semiconductors can also be exploited in solar cells and other optoelectronic devices. By adjusting the doping concentration, the bandgap of a semiconductor can be tuned to match the solar spectrum, resulting in higher efficiency and improved performance.

In addition to their optical properties, nanoscale compound semiconductors have significant applications in energy-efficient optoelectronics and solar cell devices. These materials are used in a wide range of applications, including light-emitting diodes (LEDs), solar cells, and photodetectors. LEDs are used in various electronic devices, such as smartphones, televisions, and computers, for their energy-efficient lighting. Solar cells, on the other hand, convert sunlight into electricity, making them a renewable and sustainable source of energy. Photodetectors are used in various applications, such as imaging, sensing, and communication, for their ability to detect and respond to light.

The role of compound semiconductors in the advancement of energy-efficient optoelectronics and solar cell devices is significant. These materials are highly efficient in converting sunlight into electricity, making them a viable alternative to traditional energy sources. They are also highly durable and can withstand harsh environmental conditions, making them suitable for outdoor applications. Moreover, compound semiconductors are highly flexible and can be easily integrated into various devices, making them a preferred choice for many applications.

In conclusion, Nanoscale Compound Semiconductors and their Optoelectronics Applications provides a comprehensive understanding of nanoscale compound semiconductors and their role in modern technological advancements. This book explores the fundamental properties of these materials, including their optical, size-dependent, and tunable characteristics. It provides a thorough review of key methods employed in their synthesis and characterization, emphasizing their significance in advancing energy-efficient optoelectronics and solar cell devices. Additionally, the book delves into the photocatalytic property of these materials by incorporating graphene oxides, offering a promising and emerging pathway for diverse applications. By unraveling the intricacies of nanoscale compound semiconductors, this book serves as a valuable resource for researchers, engineers, and students in the fields of materials science, electronics, and renewable energy.

Weight: 1000g
Dimension: 229 x 152 (mm)
ISBN-13: 9780128240625