dublin, February 21, 2024 /PRNewswire/ — The “6G Communications: Low Loss and Thermal Materials and Structures: Detailed Technology Analysis, Roadmap, and 32 Market Forecast Lines 2024-2044” report has been added. ResearchAndMarkets.com Recruitment.
The telecommunications industry is on the cusp of revolutionary change with the advent of 6G technology. This new research publication provides a comprehensive analysis of his burgeoning 6G communications field, with a particular focus on critical low-loss and thermal materials and structures. The report predicts promising growth and huge market opportunities beyond this. 10 billion dollars For players who can meet the unique challenges posed by 6G technology.
This report outlines the essential components for successful deployment of 6G networks, highlighting the importance of advanced materials that can manage higher frequencies, increased power consumption, and elevated thermal profiles. This cutting-edge research serves as a strategic roadmap for deep understanding of technology intricacies and market trends.
Covering a global perspective, this publication details winning compatibility, potential partnerships, acquisitions, and emerging competitors through a series of SWOT assessments, timelines, graphs, tables, and 32 forecast lines. We are investigating. Industry players can use the insights to identify untapped market gaps and strategically invest in next-generation communications technologies.
Compelling research insights into 6G materials
- A detailed look at both low-loss and thermal materials required for optimal 6G performance.
- Comparative data and SWOT analysis to identify potential partnerships and competitive advantages.
- A sophisticated roadmap that predicts a 20-year cycle of technology adoption and innovation.
- Definitive profiles of the 107 companies currently shaping the future of 6G technology.
- Forecasts featuring favorable compounds, devices, frequency bands, and regions expected to advance the 6G industry.
The report begins with an executive summary and conclusion that efficiently distills information for time-constrained professionals, followed by a deep-dive chapter on the long-awaited “6G dream.” In particular, we evaluate the evolving landscape of both low-loss dielectrics and thermal management materials across a variety of applications.
This publication reports on dielectrics at various levels, from devices to intelligent surfaces, and represents a commitment to integrated materials for this next generation technology. Meanwhile, an extensive chapter on thermal materials details innovations in cooling solutions and heat spreaders with his burgeoning 6G infrastructure and devices.
As the landscape of 6G networks expands, the potential for this market will only increase. The research compiled in this report will guide industry players looking to bet on the future of communications technology.
Key questions answered include:
- Will chemistry and companies win or lose?
- Are there potential partners, acquisitions or new competitors?
- A 20-year roadmap for decision-making, technical capabilities, and implementation?
- market gap. Are unresolved problems your opportunities?
- Evolution of 6G Phase 1 and Phase 2 by Materials, Frequency, and Features?
- 32 20-Year Forecasts for 6G Low Loss and Thermal Materials and Their Hosts?
- Do preferred compounds, forms, devices, frequencies, and active regions emerge?
Main topics covered:
1. Executive summary and conclusion with 32 market forecast lines from 2024 to 2044
1.1 Purpose of this report
1.2 Methodology of this analysis
1.3 20 main conclusions and 3 infograms
1.4 Victory and defeat examples of 6G low loss, thermal materials, and 6G frequency
1.5 Organizations developing and potential buyers of 6G hardware
1.6 How will material needs change with 6G communications?
1.7 Exploring 6G low loss materials
1.8 Exploring 6G thermal materials
1.9 2024-2044 Technology Roadmap and 32 Market Forecast Lines 2024-2044
1.10 14 Lines of 6G Low Loss and Thermal Materials Market Forecast 2024-2044
1.11 18 Line Background Forecast 2024-2044
1.12 Locations of major 6G materials and component activities around the world
2. Introduction
2.1 Why do we need 6G?
2.2 Disruptive aspects of 6G
2.3 Expanding the 6G Wish List – Hardware Implications
2.4 Forecast and current status of NTTDoCoMo, Huawei, Samsung, and Nokia
2.5 6G standard procedures finalized
2.6 Infogram: Progress from 1G to 6G Deployment (1980-2043)
2.7 Three Infograms: 6G Applications on Land, Water, Air, Low Loss and Heat Needs
2.8 Possibilities of 6G evolution
2.9 Expanding share of non-metals
2.10 Arguments against 6G
2.11 Currently known SWOT evaluation of 6G communication
2.12 Transmission distance dilemma requires advances in power, thermal and dielectrics
2.13 The Greening Dilemma – Impact on Materials
2.14 14 Applications of 20 Emerging Inorganic Compounds in Potential 6G Communications
2.15 Potential 14 applications of 10 elements in 6G communications
2.16 14 Applications of 6 Emerging Organic Families in Potential 6G Communications
2.17 Summary
2.18 Manufacturing technology for 6G high value-added materials
2.19 SWOT Assessment of 6G Communications Materials and Components Opportunities
3. Low loss materials and applications for 6G
3.1 6G Low Loss Material Definition, Requirements, and Selection
3.2 Major changes in low loss material selection from 5G to 6G
3.3 Different dielectric needs and choices for 6G
3.4 Permittivity of 19 dielectric families from 0.1 to 1 THz
3.5 Dissipation factor of 16 dielectric families from 0.1 to 1 THz: overview
3.6 Dissipation tangent of 19 dielectric groups 0.1 to 1 THz: Details
3.7 Main mentions of low loss and thermal materials in 6G research
3.8 Trends in integrated low loss materials for 6G
3.9 Compromise with 6G low-loss materials depending on format and application
3.10 Regular and special dielectrics can be applied to 6G systems
3.11 Low-loss materials for 6G base stations and distributed equipment
3.12 THz waveguide for 6G client devices, indoor and outdoor
3.13 SWOT Assessment of 6G Low Loss Materials Opportunity
4. Epsilon Near Zero ENZ Material and 6G Application
4.1 Definition and phenomenon of ENZ
4.2 Example of ENZ material development
5. 6G Thermal Management Materials and Applications: The Big Picture
5.1 Growing needs for thermal materials in 6G require further innovation
5.2 Thermal issues for 6G equipment on land and in the air
5.3 Important considerations when solving thermal problems
5.4 Thermal management structure
5.5 6G Thermal Materials Integration
5.6 Potential new and diverse thermal challenges for new suppliers
5.7 New heat pipes for 2021 and 2022: twin hole wick, two graphene options
5.8 Lessons from the latest patents: self-healing and better performing thermal interface materials
5.9 SWOT Assessment of 6G Telecommunications Thermal Materials Opportunity
6. Thermal management materials for 6G smartphones, IoT nodes and other client devices
6.1 Overview
6.2 Target activities of 17 companies for three thermal material standards
6.3 Due to 6G, 1 billion smartphones will be sold annually from 2023 to 2043
6.4 Smartphone thermal materials market area million square meters 2023-2043
6.5 Thermal Advancement from 5G to 6G Smartphones and Other Client Devices
6.6 Thermal interface materials for 6G
6.7 Internal insulation airgel WL Gore
7. 6G Thermal Management Wildcards: Thermal Metamaterials, Thermal Hydrogels, Thermoelectric Heat Pumps
7.1 Overview
7.2 Thermal Hydrogels for Passive Cooling of 6G Microelectronics and Photovoltaics
7.3 Thermal Metamaterials for 6G Devices, Infrastructure, and Solar Power
7.4 Radiative cooling for solar power generation in general
7.5 Thermal Metamaterials – Plasmonics Inc. and Radi-Cool
7.6 nanometa Technologies Co., Ltd.
7.7 6G Chip Thermoelectric Temperature Control
7.8 Non-toxic thermoelectric elements
8. Solid state cooling
8.1 Definition and necessity of solid state cooling
8.2 Solid State Cooling Tool Kit
8.3 11 main conclusions and 5 infographics
8.4 Most needed compounds for future solid-state cooling
8.5 Comparison of 12 solid-state cooling operating principles with 10 functions
8.6 Solid-State Cooling Research Pipeline and Technology Readiness Level by Topic
8.7 The new center of solid-state cooling
8.8 Functions and forms of solid-state cooling and heating protection
8.9 The future of thermal interface materials and other cooling by thermal conduction
8.10 SWOT evaluation of silicone thermal conductive materials
8.11 SWOT evaluation of solid state cooling in general and 7 new versions
8.12 SWOT evaluation of daytime passive radiative cooling PDRC
8.13 SWOT assessment of self-cooling radiative metafabric
8.14 SWOT evaluation of anti-Stokes fluorescence cooling
8.15 SWOT Assessment of Electrical Calorific Cooling and Thermal Management
8.16 SWOT evaluation of magnetocaloric cooling
8.17 SWOT Evaluation of Mechanical Calorie Cooling
8.18 SWOT Assessment of Thermoelectric Cooling and Temperature Control
8.19 Widely Used and Suggested Unwanted Materials: This Is Your Opportunity
8.20 Three cooling technology attention and maturity curves 2024, 2034, 2044
9. Metamaterials for 6G applications
9.1 Overview
9.2 Meta-atoms and patterning options
9.3 Comparison of commercial, operational, theoretical and structural options
9.4 Metamaterial patterns and materials
9.5 Six metamaterial formats and examples needed for 6G
9.6 Metasurface Primer
9.7 Hypersurface
9.8 Long-term outlook for metamaterials as a whole
9.9 Metasurface energy harvesting is likely to become a reality in 6G
9.10 GHz, THz, infrared and optical metamaterials
9.11 SWOT assessment of metamaterials and metasurfaces in general
Companies mentioned
- active airgel
- airgel technology
- airgel uk
- AGC
- analog device
- Anritsu
- apple
- arctic
- aspen airgel
- Beacom
- BT
- cabot company
- china communications
- cold case gear
- corning
- Covestro
- degliter
- Dow
- dupont
- Enersen
- Ericsson
- fiat
- Finister
- Fujitsu
- gentelm
- GLPOLY
- greener wave
- guangdong allison high tech
- Guizhou Aerospace
- Henkel
- Hitachi
- HTC
- huawei
- Kyocera Corporation
- Kymeta
- lenovo
- LG
- Metamaterial Co., Ltd. (currently Meta)
- metawave
- microsoft
- mitsubishi
- motorola
- Murata
- nano tech
- nanometa technology
- NEC
- net gear
- nylium
- Noctua
- nokia
- NTT
- NTT Docomo
- Nubia
- Oppo
- orange
- panasonic
- parker hannifin
- plasmonics
- Qualcomm
- Quechtel
- radi cool roger
- Rohde Schwarz
- servich
- samsung
- shot
- Sekisui
- sharp
- airgel technology in shenzhen
- Shenzhen Zhouming Technology
- Shinetsu
- sierra
- SNCF
- sol aero
- Sony
- Space liquid metal technology development Jiangsu province
- spectro lab
- Strauss
- Suzhou Daishan
- TDK
- telefonica
- Telit
- thermal graphite
- thermionic
- Toyota
- Tubitac
- Vivo
- WL Gore
- wuhan leikas
- Amoy Namete
- xiaomi
- ZTE
For more information about this report, please visit https://www.researchandmarkets.com/r/px4d9o.
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