Terahertz and optical materials and components 2024-2044 technology roadmap

dublin, March 11, 2024 /PRNewswire/ — “6G Communications: Terahertz and Optical Materials, Components 2024-2044, 32 Forecast Lines, Technology Roadmap” report added. ResearchAndMarkets.com Recruitment.

This unique report identifies vast optical materials and component opportunities from 6G communications, primarily optical systems.

The report begins with a detailed glossary and a list of 96 of the companies mentioned. The executive summary and conclusion are easy to read, even for those in a hurry. 58 pages include essential explanations, new infograms, opportunity identification, key players, SOFT assessment, roadmap, and 17 forecasts from 2023 to 2043. There is no equation. No nostalgia.

Understand why optical wireless communication needs to become commonplace in 6G systems. This includes overcoming the terahertz gap due to insufficient materials and device performance in the far infrared (above 0.3THz). Here we discuss important photovoltaic and other optical materials manufacturing technologies. Both are discussed in detail later in the report.

6G will use a huge amount of optical fiber, including “deep fiber” to each room in a building and underwater fiber. Most of it will be existing shared fiber made using traditional methods, but there are also some aspects that are unique to 6G, so we discuss fiber optics in his 6G system on page 13 of chapter 9, ending with a SWOT assessment. To do.

Now that we know that graphene is one of the most popular materials in the optical 6G research pipeline, we will end the report with a deeper discussion without repeating what came before. Chapter 10, “Graphene and Other His 2D Materials in 6G,” is 17 pages long and reveals his six potential applications in 6G, along with formats, alternatives, auxiliary materials, and analysis. This example covers near-infrared, far-infrared, and visible light frequencies.

The new report answers questions such as:

• Why is the huge hardware cost of 6G justified only by the ubiquity of superior optical performance?
• Why are there so many opportunities to add value to your expertise in silica, graphene, alumina with sapphire, 3-5 compounds, silicon nitride, and chalcogenides?
• What new forms have premium pricing? What else?
• What materials are on the decline with the advent of 6G?
• Why will the first 6G phase from 2030 require a lot of optical fiber and some optical wireless communications? When?
• Why is a second phase of 6G needed to achieve the promised ubiquitous superior performance?
• Why should we primarily use 0.3THz far-infrared to ultraviolet optics? When?
• Huge new markets for THz cables, reconfigurable intelligent surfaces, long-range optical wireless transmission hardware, solar-powered 6G drones, deep fiber optics, optical power feeding and optical communication client devices? Why? when? what else?
• Detailed 20-year forecast, roadmap, new infogram and SOFT assessment?

Main topics covered:

1 overview and 17 predictions for 2023-2043
1.1 6G Report Series
1.2 Purpose of this report
1.3 Giant companies with huge opportunities
1.4 Subject of this report
1.5 Methodology of this analysis
1.6 Key conclusions: 6G optical systems from 0.3THz to UV
1.7 Key Conclusions: 6G Materials and Components from 0.3THz to UV
1.8 Wireless communications and the anticipated two stages of 6G deployment
1.9 6G goals of NTT, Huawei, Samsung, Nokia, China, etc.
1.10 General parameters of 5G and 6G wireless showing some increasing challenges
1.11 How 6G transmission hardware delivers much better performance than 5G
1.12 6G Phase 1 and 2 Spectrum
1.13 16 key selling features of 6G for what the four frequency bands can offer
1.14 Infogram: 6G Massive Hardware Deployment, Compromises, and the Importance of Optics
1.15 6G Comparison for Aerospace Vehicles – Comparison of the good and bad points of 7 types
1.16 Underwater and underground 6G transmission options – Market gap
1.17 Infogram: Possible 6G optical hardware suppliers including 0.3-1THz: Examples
1.18 Infogram: 6G transmission systems using infrared, visible and ultraviolet frequencies
1.19 How will material needs change with 6G communications?
1.20 Transmission distance dilemma
1.21 Infogram: Terahertz gap with limited dielectric and active device options
1.22 Overcoming poor dielectric, emitter, and detector terahertz gaps
1.23 Three types of 6G THz communication methods
1.24 THz integrated circuit options
1.25 Overcoming the problem of free-space optical FSO attenuation in air
1.26 32 Examples of Suitable FSO Hardware and Systems Suppliers by Country
1.27 6G Version Reconfigurable Intelligent Surface RIS SWOT Assessment
1.28 SWOT evaluation of terahertz waveguide in 6G system design
1.29 SWOT evaluation of fiber optic FiWi in 6G system design
1.30 SWOT assessment of metamaterials and metasurfaces
1.31 SWOT Assessment of 6G THz Low Loss Materials Opportunity
1.32 Four 6G Roadmaps from 2023 to 2043
1.33 6G Materials, Devices, and Background – 17 Predictions from 2023 to 2043
1.34 Locations of major 6G materials and components activities around the world 2023-2043

2. Introduction
2.1 6G goals and our scope of coverage
2.2 Why optical wireless communication is essential for promised 6G performance
2.3 Infogram: 6G aspirations across the globe
2.4 6G rural challenges
2.5 6G Underwater and Underground – Market Gap
2.6 Glossary
2.7 Why does 6G require large infrastructure and many transmission media?
2.8 Essential 6G tools: RIS, OWC, cable trunking (fiber and THz)
2.8.1 Optical wireless communication OWC
2.8.2 Structure and potential functionality of reconfigurable intelligent surface RIS
2.9 Green Power Dilemma with Active RIS and Other 6G Infrastructure
2.10 Materials for Solar Power in Client Devices with 6G Infrastructure and Double Power
2.11 6G component manufacturing technology and product integration

3. 6G optical wireless communication OWC
3.1 Optical wireless communication OWC
3.2 Definition and scope of OWC and its subsets
3.3 Infogram: Potential 6G transmission system using OWC
3.4 Infrared IR, Visible VL and Ultraviolet UV of 6G in Air: Issues and Parameters
3.5 FSO System Basics
3.6 Inclusion or defaulting into LiFi
3.7 Aerospace OWC expected in 6G
3.8 FSO Attenuation in Air: Physics, Problems, and Solutions
3.9 OWC emitter and detector components and materials
3.10 FSO Hardware and Systems Suppliers 32 Examples and Country Analysis

4. Metamaterials and metasurfaces for THz, IR, and visible 6G
4.1 Nine potential applications for metamaterials in 6G
Applications of 4.2 GHz, THz, infrared and optical metamaterials
4.3 Meta-atoms and patterning options
4.4 Optical metamaterial patterns and options
4.5 Comparison of commercial, operational, theoretical and structural options
4.6 Six formats and examples of metamaterials needed for 6G
4.7 Metasurface
4.8 Hypersurface
4.9 Patterning of active materials
4.10 Optical ENX Metamaterial
4.11 Potential of metasurface optical energy harvesting for 6G
4.12 Possibility of 6G cooling with infrared-manipulating metamaterials
4.13 Metamaterial companies capable of delivering 6G in top THz, IR, and optical frequencies
4.14 Long-term overview of metamaterials as a whole
4.15 SOFT evaluation of metamaterials and metasurfaces

5. 6G Reconfigurable Intelligent Surface in 0.3-10THz Far Infrared
5.1 Fundamentals of reconfigurable intelligent surfaces
5.2 How Metasurface RIS Hardware Works
5.3 Semi-passive and active RIS materials and components
5.4 6G Reconfigurable Intelligent Surface 0.1-1THz Cost Tier Challenges
5.5 RIS improvements planned by 2045
5.6 Recognition that hardware is theoretically behind in 2022
5.7 Major RIS Standards Initiatives ETSI
5.8 RIS for 6G base station
5.9 RIS-Integrated User-Centric Network: Architecture and Optimization
5.10 RG RIS control issues
5.11 Evaluation of nine tuning device families for RIS from recent research pipelines
5.12 Progress beyond 2022
5.13 Advancements to 1THz RIS for 6G including graphene, vanadium dioxide, GST, and GaAs

6. 6G reconfigurable intelligent surfaces in near-infrared and visible light
6.1 Overview
6.2 Near-infrared and visible light RIS
6.3 Near-infrared RIS with amplification function
6.4 RIS-enabled LiFi
6.5 Optical devices that enhance or replace RIS
6.6 Optical RIS generally starts from 2022
6.7 SWOT assessment to guide future RIS design

7. Dielectrics, passive optical materials and semiconductors from 6G 0.3THz to visible
7.1 Dielectrics
7.2 Selection of semiconductor materials for 6G
7.3 Thermoelectric temperature control materials for 6G chips and lasers
7.4 Other developments in 2022
7.5 Research trends

8. THz cable waveguide and client device waveguide for 6G transmission
8.1 Terahertz waveguide cable: necessity and current status
8.2 6G waveguide cable design and materials
8.3 Fluoropolymers
8.4 Polypropylene
8.5 Polyethylene/Polypropylene Metamaterial THz Waveguide
8.6 Manufacture of polymer THz cables on long reels
8.7 THz waveguide grating etched on metal wire
8.8 THz waveguides from InAs, GaP, sapphire, etc. for emitter boosting, sensing, etc.
8.9 SWOT evaluation of THz cables and waveguides in 6G system design

9. Optical fiber for 6G systems
9.1 Overview
9.2 Fiber optic cable design and materials
9.3 Optical fiber operation
9.4 Limit fiber and electronics usage to save costs
9.5 Occurrence of serious attacks
9.6 Erbium-doped fiber amplifier EDFA
Photonics-defined radio and photonics integration for 9.7 THz 6G
9.8 SWOT evaluation of optical fiber in 6G system design

10. Graphene and other 2D materials in 6G
10.1 6G Overview and 6 Related Applications
10.2 Comparison of graphene THz sensing and alternatives
10.3 Graphene Plasmonics for 6G THz Metasurfaces, Modulators, Splitters, and Routers
10.4 Graphene gate THz transistor for 6G optical rectifier, optical absorber
10.5 Other 2D materials up to 10THz for wireless communications: MoS, BN, perovskites

Companies mentioned

• acuity brand
• Adva
• airbus
• Airlinx Communications
• apple
• arcera laser
• AT&T
• AVIC
• BAE Systems
• boeing
• bridge lux
• broadcom
• CAAA
• cable store
• canon
• oak
• Cassidian
• Chemours
• china communications
• Cisco
• corning
• deloitte
• dupont
• echodyne
• Elbana Photonics
• Ericsson
• eurocom
• evolve technology
• Fractal antenna system
• fSONA
• general electric
• gentelm
• geodesy
• greener wave
• honeywell
• huawei
• fuse net
• dropsy
• inmarsat
• Institute Fresnel
• intel
• iQLP
• iridium chimeta
• lesson
• LG
• light point
• ll-Vl Co., Ltd.
• lumen
• media tech
• Merck
• meta
• metacept
• metwave
• nanometatechnology
• NASA Swift Engineering
• Nazca group
• nokia
• northern high tech
• Novasol
• bad debt
• NTT
• NTT Docomo
• omnitech
• Oxford PV
• panasonic
• philips
• Vital Comware
• plain tree
• plasmonics
• Prismian
• Purify
• Qualcomm
• Raj Cool
• Infrastructure red lines
• SA Photonics
• servich
• samsung
• Sekisui
• sensor metrics
• sharp
• showman laser
• SK Telecom
• sol aero
• Sony
• space mobile
• space x
• Spectro Love Star Link
• Taiyo Yuden
• Thales Alenia
• Thermion
• TII
• Toshiba
• trimble
• Swallow
• Tubitac uekae
• Viacom
• Viasat
• Vishay
• great wireless
• YOFC
• ZTE

For more information on this report, please visit https://www.researchandmarkets.com/r/9tljip.

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