6G Communications Dielectric, Thermal and Transparent Materials: Markets, Technology 2025-2045
상품코드:1548194
리서치사:Zhar Research
발행일:2024년 08월
페이지 정보:영문 432 Pages
라이선스 & 가격 (부가세 별도)
한글목차
무선통신의 각 세대는 전송 주파수를 높여 성능을 향상시키고 있으며, 6G에서는 광대역 갭 반도체와 특히 유전체가 요구됩니다. 예를 들어 신호를 전송하는 릴레이는 유연한 유전체 기판 위에 상변화 유전체로 튜닝된 메타표면이 될 것이며, 6G에서는 광유전체를 이용한 무선 원적외선 전송으로 진화할 것입니다.
새 세대를 거듭할수록 더 많은 열을 발생시키는 인프라가 채택됨에 따라 냉각이 중요해지고, 특히 유전체를 기반으로 한 새로운 고체 냉각이 주목받고 있습니다. 또한 인프라 및 클라이언트 장비의 자체 전원 공급을 위해 WBG 및 유전체를 사용하는 열전 및 광전 전력을 채택합니다. 하드웨어는 점점 더 투명해지고, 수용하기 쉬워지고, 성능도 향상되고 있습니다. 큰 기회는 유전체, 초광대역 UWBG 반도체, 열 재료, 투명성과 같은 주제에서 찾을 수 있습니다.
장 구성 :
8장
SWOT 평가 :
16항목
예측 라인 :
30 라인
인포그램 :
67개
기업 수 :
107사
페이지 수 :
432 페이지
6G 통신 유전체·열재료·투명 재료의 기술과 시장을 조사했으며, 6G 유전체·열재료·투명 재료의 중요성, 주요 재료 R&D 동향, 기술 로드맵, 주요 재료 시장 규모 추이·예측, 6G 부가가치 재료와 디바이스 제조 기술에 종사하는 중소기업 등을 정리하여 전해드립니다.
제5장 비가시성이 수용과 성능 문제를 해결 : 투명 패시브 반사 어레이와 올 라운드 STAR RIS
2024년의 개요와 사례
2024-5년 6G 전송 처리면의 투명화 상황
시각적으로 투명 또는 불투명하게 할 수 있는 6G빔 처리면의 옵션
투명한 IRS와 RIS는 거의 어디에라도 갈 수 있다.
투명 패시브 지능형 반사면 IRS : Meta Nanoweb-R Sekisui
광학적으로 투명하고 투과성 있는 밀리미터파 및 테라헤르츠 RIS
동시 투과·반사형 STAR RIS
STAR RIS SWOT 평가
기타 연구논문 : 2024년
기타 연구논문 : 2023년
제6장 6G 통신의 메타매트리얼 기초, 트랜스미션, 에너지 회수 등
개요와 잠재적인 용도, 2024년의 진보
인포그램 : 5G와 6G에서 메타매트리얼의 위치설정
6G로 검토되고 있는 전자 메타매트리얼 클래스
5G 및 6G 통신용 메타매트리얼 반사 어레이와 RIS
2024년의 주요 진보를 포함한 메타매트리얼 패턴과 재료
6G RIS 윈도우를 포함한 2 기능 메타표면를 포함한 초곡면
메타표면 6G 에너지수확기술 : 2024년 눈부신 연구의 진보
2024년에 7개의 진보를 이루는 6G용 조정 가능 메타매트리얼
GHz, THz, 적외선, 가시광선 메타매트리얼의 많은 새로운 용도가 투자 리스크를 경감
메타매트리얼과 메타표면의 SWOT 평가
메타매트리얼 전체의 장기적 전망
제7장 6G 0.3THz로부터 가시광선 6G 트랜스미션을 위한 유전체, 광학 재료, 반도체
유전체의 정의, 6G 유용성, 리스크 회피, 2024년 이후 연구 진전의 예
고유전율 및 저유전율 6G 저손실 재료의 탐구
6G용 중요한 유전체 배합의 등장
6G 옵트로닉스용 상변화 유전체, LCD 및 대체품
테라헤르츠 도파 케이블 및 소형 유닛
6G용 근적외선 광섬유의 미래
제8장 6G 부가가치 재료와 디바이스 제조 기술에 종사하는 중소기업
AALTO HAPS(영국·독일·프랑스)
Echodyne(미국)
Evolv Technology(미국)
Fractal Antenna Systems(미국)
Greenerwave(프랑스)
iQLP(미국)
Kymeta Corp.(미국)
LATYS Intelligence(캐나다)
Meta Materials(캐나다)
Metacept Systems(미국)
Metawave(미국)
Pivotal Commware(미국)
SensorMetrix(미국)
Teraview(미국)
KSA
영문 목차
영문목차
Summary
Time for a report on 6G dielectrics, thermal and transparent materials. Why? Each generation of wireless communication increases performance by increasing transmission frequency. With 6G, that demands wide bandgap WBG semiconductors and particularly dielectrics. For example, the relay passing on the signal becomes a metasurface tuned with phase change dielectric on a flexible dielectric substrate as one option. 6G will evolve to add wireless far infrared transmission using optical dielectrics.
Every new generation employs more infrastructure generating more heat so cooling comes center stage, notably the new solid-state cooling based on dielectrics, and self-powering of infrastructure and client devices employs thermoelectrics and photovoltaics using WBG and dielectrics. Hardware increasingly becomes transparent to be acceptable (invisible facade overlayers, smart windows) and better performing (360-degree reconfigurable intelligent surfaces). Your big opportunity pivots to the overlapping topics of dielectrics, ultra-wide bandgap UWBG semiconductors, thermal materials and transparency and only this report covers them all. Vitally, it analyses the flood of advances in 2024, forecasting 2025-2045 because so much has changed recently.
Commercially oriented, the report has:
Chapters:
8
SWOT appraisals:
16
Forecast lines:
30
Infograms:
67
Companies:
107
Pages:
432
"6G Communications Dielectric, Thermal and Transparent Materials : Markets, Technology 2025-2045" starts with an Executive Summary and Conclusions clearly pulling everything together for those with limited time. Those 26 pages are mainly lucid new infograms, the 13 key conclusions and 2025-2045 roadmaps. The 30 forecast lines then add pages as both tables and graphs. The 41-page Introduction gives a thorough background to 6G hardware with SWOT appraisals and introduces some 2024 research.
Flood of 2024 research analysed
Then come two large chapters on your thermal materials and device opportunities in the light of breakthroughs in 2024 with a large amount of 2024 research analysed. Chapter 3 "6G thermal management materials and applications" (94 pages) presents the overall thermal picture, with the latest view of needs matched to the latest toolkit. That includes new thermally conductive polymers and composites, thermal metamaterial, hydrogel, aerogel, ionogel, pyrolytic graphite and graphene for both 6G infrastructure and client devices. There is even deep coverage of thermal systems you may wish to supply.
6G cooling becomes a large opportunity
Cooling emerges as the major thermal requirement due to 6G infrastructure making more heat and requiring client devices to manage heat in smaller formats. Indeed, emerging markets are in hotter places such as India and global warming also contributes to the 6G cooling problem. Conventional vapor compression cooling heats cities by up to several degrees and is not fit-and-forget so attention turns to solid state cooling for 6G merging with its hosts such as high-rise buildings and loitering stratospheric drones.
Consequently, a dedicated Chapter 4, "Solid state cooling for 6G using dielectric, thermal and transparent materials" (35 pages) analyses this favourite for infrastructure and client devices on the 20-year view. See eleven primary conclusions, most needed compounds for future solid-state cooling in 211 recent research announcements and twelve solid-state cooling operating principles compared by 10 capabilities. The research pipeline of solid-state cooling by topic vs technology readiness level is presented in three new maturity curves 2025, 2035, 2045. Thermal interface materials, thermoelectric, caloric, passive daytime radiative and other cooling principles are covered. Interestingly, your ultra-WBG materials such as SiN, AlN, BN and dielectrics such as silicas and aluminas are here need for cooling but later identified for many other 6G uses as well. It is found that solid state cooling suitable for 6G mainly needs inorganics whereas the other needs addressed in the report mainly need identified polymers.
Invisibility
Invisible 6G infrastructure will be more acceptable and functional from solar drones at 20km to satellites and transparent materials and devices, two major types being covered in Chapter 5, "Invisibility solves acceptance and performance problems: Transparent passive reflect-arrays and all-round STAR RIS", its 32 pages including two SWOT appraisals and a large amount of research progress in 2024.
Dielectric multifunctional metamaterials
Chapter 6, "Metamaterial basics, transmission, energy harvesting and more for 6G communications" takes 20 pages the assess a large amount of 2024 advance and give a SWOT appraisal. Understand why 6G demands progress from metal patterning on epoxy laminate to flexible, transparent, self-cleaning - even all dielectric - metamaterials for making 6G photovoltaics follow the sun and keep cool and for handling THz, near IR and visible light. See the remarkable research progress in 2024 achieving just that and also making electricity from movement, useful in 6G client devices.
Optical transmission materials and devices emerging
Then comes a large Chapter 7, "Dielectrics, optical materials, semiconductors for 6G 0.3THz to visible light 6G transmission" at 109 pages. Mostly dielectrics, it also includes ultra-wide gap semiconductors coming in and the flood of new research progress on all these topics. Overall, the important performance parameters are identified and, for dielectrics, a very detailed look at permittivities and dissipation factors DF for 20 dielectric families at the higher 6G frequencies. Matched against needs, it reveals that the emerging market for dielectrics with intermediate DF, low permittivity such as polyimides will be large, that for low DF, low permittivity such as porous silicas will be significant but there will also be a market for high permittivity, low DF such as hafnium oxide. What about Fluoropolymers (PBVE, PTFE, PVDF), epsilon near zero materials, THz and optical tuning materials? It is all here with a host of 2024 research advances and latest views.
Partners and acquisitions
To save time, you will need partners and acquisitions, mostly small companies, so the final Chapter 8, "Some small companies involved in 6G added value material and device manufacturing technologies" in 40 pages, profiles 14 for you to consider.
An important takeaway from, "6G Communications Dielectric, Thermal and Transparent Materials : Markets, Technology 2025-2045" is that the most successful materials in research for 6G thermal, dielectric and transparent applications have exceptionally varied morphologies, formats and applications in the preferred solid-state phase and are useful in many new composites. Overall, they are fairly-evenly divided between inorganics and organics with a trend to multifunctional smart materials using both.
Caption: Thermal, dielectric, UWBG materials of interest for 6G: latest research priorities. Source: Simplified image from Zhar Research report, "6G Communications Dielectric, Thermal and Transparent Materials : Markets, Technology 2025-2045".
Table of Contents
1. Executive Summary and Conclusions with roadmaps and forecast lines 2025-2045
1.1. Purpose of this report
1.2. Methodology of this analysis
1.3. Key conclusions: What will drive 6G success, landscape infogram
