Emergent Micro- and Nanomaterials for Optical, Infrared, and Terahertz Applications

A review of emerging materials for optical, infrared, and terahertz applications, highlighting their unique advantages, limitations, and potential applications.

Format: Hardback
Length: 429 pages
Publication date: 27 October 2022
Publisher: Taylor & Francis Ltd

Here is the rephrased text:

Optical, infrared, and terahertz applications have a wide range of potential uses, and a variety of emergent materials have emerged to meet these needs. This paper provides a comparative analysis of these materials, highlighting their unique advantages, limitations, and application scopes. It also provides an up-to-date record of achievements and progress in cutting-edge optical, infrared, and terahertz applications. Furthermore, the paper offers a comprehensive overview to connect multidisciplinary fields such as materials, physics, and optics, serving as a basis for future progress.

The field of optical, infrared, and terahertz applications has seen significant advancements in recent years, driven by the increasing demand for advanced technologies. These applications require materials that have unique properties such as high transparency, low absorption, and high refractive index. Emergent materials such as graphene, carbon nanotubes, and metamaterials have emerged as promising candidates for these applications.

Graphene is a two-dimensional material made up of carbon atoms arranged in a honeycomb structure. It has a high transparency, low absorption, and high refractive index, making it ideal for optical applications such as optical filters, optical devices, and optical communication systems. Carbon nanotubes are cylindrical structures made up of carbon atoms, and they have a high aspect ratio, which makes them suitable for infrared applications such as infrared sensors, infrared imaging, and infrared communication systems. Metamaterials are artificial materials that have designed properties that are not found in nature. They can be used for a wide range of applications, including optical, infrared, and terahertz applications.

One of the key advantages of graphene is its high transparency, which allows it to transmit a large portion of the visible spectrum. This makes it ideal for use in optical devices such as solar cells, optical filters, and optical communication systems. Another advantage of graphene is its high electrical conductivity, which makes it suitable for use in electronic devices such as transistors and touch screens. Carbon nanotubes, on the other hand, have a high aspect ratio, which makes them suitable for infrared applications such as infrared sensors, infrared imaging, and infrared communication systems. They also have a high thermal conductivity, which makes them suitable for use in thermal management applications.

Metamaterials have a wide range of applications in optical, infrared, and terahertz applications. For example, metamaterials can be used to create optical devices that have a narrow bandwidth, which is useful for optical communication systems. They can also be used to create optical devices that have a high reflectivity, which is useful for solar cells. Metamaterials can also be used to create infrared devices that have a high sensitivity, which is useful for infrared imaging and sensing.

Despite the many advantages of emergent materials such as graphene, carbon nanotubes, and metamaterials, there are also some limitations that need to be addressed. For example, graphene is a brittle material, which makes it difficult to process and manufacture. Carbon nanotubes are also difficult to process and manufacture, and they have a limited range of applications. Metamaterials, on the other hand, are difficult to design and manufacture, and they have a limited range of applications.

In conclusion, optical, infrared, and terahertz applications have a wide range of potential uses, and a variety of emergent materials have emerged to meet these needs. This paper provides a comparative analysis of these materials, highlighting their unique advantages, limitations, and application scopes. It also provides an up-to-date record of achievements and progress in cutting-edge optical, infrared, and terahertz applications. Furthermore, the paper offers a comprehensive overview to connect multidisciplinary fields such as materials, physics, and optics, serving as a basis for future progress.

Weight: 980g
Dimension: 234 x 156 (mm)
ISBN-13: 9781032065052