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Two-Dimensional Materials for Mid-infrared Photonic and Photoelectric Applications
- 1st Edition - December 1, 2099
- Authors: Han Zhang, Zhe Shi, Rui Cao, Chunyang Ma
- Language: English
- Paperback ISBN:9 7 8 - 0 - 3 2 3 - 9 5 4 6 8 - 6
- eBook ISBN:9 7 8 - 0 - 3 2 3 - 9 5 4 7 0 - 9
Two-Dimensional Materials for Mid-infrared Photonic and Photoelectric Applications reviews the recent developments of two-dimensional (2D) materials for applications in mid-in… Read more
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Request a sales quoteTwo-Dimensional Materials for Mid-infrared Photonic and Photoelectric Applications reviews the recent developments of two-dimensional (2D) materials for applications in mid-infrared (MIR) photonics.
First, the development of 2D materials is introduced beginning with the discovery of graphene in 2004. Then, MIR photonic applications are presented in detail. Third, 2D materials that are suitable for MIR photonic applications are discussed, including their synthesis processes and properties. Additionally, novel 2D materials that are suitable for MIR photonic applications beyond the commonly used graphene, black phosphorous, and transition metal dichalcogenides are presented. These include 2D Te (tellurene), transition metal trichalcogenides (TiS3, TiSe3), tetradymites (Bi2S3,Bi2Se3,Bi2Te3), multinary layered materials (CuIn7Se11, Ta2NiSe5), topological insulators, etc. Fourth, various photonic applications of 2D MIR materials are addressed, including light emission devices, modulators, photodetectors, imaging, integrated MIR chips and so forth. Finally, the unresolved challenges in this area are examined.
Two-Dimensional Materials for Mid-infrared Photonic and Photoelectric Applications is suitable for those in academia and R&D in the subject areas of materials science and engineering, particularly those focusing on nanomaterials or optoelectronics and photonics application areas.
First, the development of 2D materials is introduced beginning with the discovery of graphene in 2004. Then, MIR photonic applications are presented in detail. Third, 2D materials that are suitable for MIR photonic applications are discussed, including their synthesis processes and properties. Additionally, novel 2D materials that are suitable for MIR photonic applications beyond the commonly used graphene, black phosphorous, and transition metal dichalcogenides are presented. These include 2D Te (tellurene), transition metal trichalcogenides (TiS3, TiSe3), tetradymites (Bi2S3,Bi2Se3,Bi2Te3), multinary layered materials (CuIn7Se11, Ta2NiSe5), topological insulators, etc. Fourth, various photonic applications of 2D MIR materials are addressed, including light emission devices, modulators, photodetectors, imaging, integrated MIR chips and so forth. Finally, the unresolved challenges in this area are examined.
Two-Dimensional Materials for Mid-infrared Photonic and Photoelectric Applications is suitable for those in academia and R&D in the subject areas of materials science and engineering, particularly those focusing on nanomaterials or optoelectronics and photonics application areas.
- Provides an introduction to the synthesis, structure, and properties of 2D materials candidates for mid-infrared (MIR) photonics applications
- Discusses potential 2D materials-based MIR photonics applications such as light-emitting devices, modulators, photodetectors, imaging, integrated chips, and more
- Reviews challenges to commercial translation of 2D materials for MIR photonics and potential opportunities to address these obstacles
Materials Scientists and Engineers, Physicists
1: Introduction
2: 2D material candidates and their structure for MIR photonic applications
2.1 Graphene
2.2 Black phosphorus
2.3 Transition metal dichalcogenides
2.4 Transition metal trichalcogenides
2.5 Tellurene
2.6 multinary layered materials
2.7 Topological insulator
2.8 2D heterostructure
2.9 Polaritonic 2D materials
2.10 Other 2D materials
3: Synthesis of 2D material candidates
3.1 Synthesis methods
3.1.1 CVD
3.1.2 MBE
3.1.3 PVD
3.1.4 LPE
3.1.5 Solution synthesis
3.1.6 Thermal evaporation
3.2 Larger area 2D materials and its heterostructure growth
4: Properties of 2D materials candidates
4.1 Electrical properties
4.2 Optical properties
4.3 Thermoelectric properties
4.4 Stability
4.5 Other properties
5: Mid light emission devices
5.1 Spontaneous emission
5.2 Coherent light source
5.3 Laser
6: MIR modulators
6.1 All optical approach
6.2 Electro-optic approach
6.3 Other approaches
7: 2D materials based MIR Photodetectors
7.1 Photodetectors
7.2 Imaging
8: MIR gas sensor based on 2D materials
9: MIR quantum measurements based on 2D materials
10: Perspectives
2: 2D material candidates and their structure for MIR photonic applications
2.1 Graphene
2.2 Black phosphorus
2.3 Transition metal dichalcogenides
2.4 Transition metal trichalcogenides
2.5 Tellurene
2.6 multinary layered materials
2.7 Topological insulator
2.8 2D heterostructure
2.9 Polaritonic 2D materials
2.10 Other 2D materials
3: Synthesis of 2D material candidates
3.1 Synthesis methods
3.1.1 CVD
3.1.2 MBE
3.1.3 PVD
3.1.4 LPE
3.1.5 Solution synthesis
3.1.6 Thermal evaporation
3.2 Larger area 2D materials and its heterostructure growth
4: Properties of 2D materials candidates
4.1 Electrical properties
4.2 Optical properties
4.3 Thermoelectric properties
4.4 Stability
4.5 Other properties
5: Mid light emission devices
5.1 Spontaneous emission
5.2 Coherent light source
5.3 Laser
6: MIR modulators
6.1 All optical approach
6.2 Electro-optic approach
6.3 Other approaches
7: 2D materials based MIR Photodetectors
7.1 Photodetectors
7.2 Imaging
8: MIR gas sensor based on 2D materials
9: MIR quantum measurements based on 2D materials
10: Perspectives
- No. of pages: 500
- Language: English
- Edition: 1
- Published: December 1, 2099
- Imprint: Elsevier
- Paperback ISBN: 9780323954686
- eBook ISBN: 9780323954709
HZ
Han Zhang
Han Zhang received his B.S. degree from Wuhan University (China) in 2006 and Ph.D. from Nanyang Technological University (Singapore) in 2010. He is currently a Distinguished Professor and Director of the Shenzhen Key Laboratory of 2D Materials and Devices, and the Shenzhen Engineering Laboratory of Phosphorene and Optoelectronics, Shenzhen University, China. His current research focus is 2D materials-based photonic applications.
Affiliations and expertise
Collaborative Innovation Center for Optoelectronic Science and Technology, International Collaborative Laboratory of 2D Materials for Optoelectronic Science and Technology of Ministry of Education and Guangdong Province, Shenzhen University, ChinaZS
Zhe Shi
Dr. Zhe Shi is a Lecturer at Xuzhou University of Technology. Zhe Shi graduated from Jilin University in 2018 with a PhD. Degree. In 2018, he joined Shenzhen University as a Post Doctor under Prof. Zhang, and joined the School of Physics and New Energy, Xuzhou University of Technology as a lecturer in 2020. His research focuses on topics related to 2D materials based optoelectronic and photovoltaic device applications.
Affiliations and expertise
School of Physics and New Energy, Xuzhou University of Technology, ChinaRC
Rui Cao
Rui Cao graduated from Macau University of Science and Technology in 2020 with a PhD. Degree. In 2020, he joined Shenzhen University as a postdoctor under Prof. Zhang. His research mainly focuses on topics related to 2D materials based photonic applications.
Affiliations and expertise
Collaborative Innovation Center for Optoelectronic Science and Technology, International Collaborative Laboratory of 2D Materials for Optoelectronic Science and Technology of Ministry of Education and Guangdong Province, Shenzhen University, ChinaCM
Chunyang Ma
Dr. Ma graduated from Jilin University in 2018 with a PhD. Degree. In 2018, he joined Shenzhen University as a postdoctor under Prof. Zhang. His research mainly focuses on topics related to 2D materials-based ultrafast optical and nonlinear optics applications.
Affiliations and expertise
Collaborative Innovation Center for Optoelectronic Science and Technology, International Collaborative Laboratory of 2D Materials for Optoelectronic Science and Technology of Ministry of Education and Guangdong Province, Shenzhen University, Shenzhen, China