6G通讯的低损耗热材料和结构：详细的技术分析、路线图和32个市场预测线(2024-2044)

Zhar Research 执行长Peter Harrop 博士表示： "满足6G 对低损耗热材料和结构的需求代表着一个价值超过100 亿美元的市场。它们位于频率更高、功耗更高的较热基础设施中，和更小的客户端设备。”

来源：6G 通讯的低损耗热材料和结构：详细的技术分析、路线图和 32 个市场预测线（2024-2044 年）

本报告调查了6G通讯用低损耗/热材料和结构的市场，涵盖了6G环境的趋势和前景、6G低损耗材料及其应用、6□□G热管理材料及其应用、它编制了地图、市场规模趋势和预测、影响市场成长的因素以及市场机会分析。

目录

第 1 章执行摘要/概述/32 条市场预测线（2024-2044 年）

第 2 章简介

• 为什么我们需要 6G？
• 6G 的颠覆性面
• 扩大 6G 愿望清单 - 对硬体的影响
• NTTDoCoMo、华为、三星和诺基亚的预测和现状
• 6G标准
• 资讯图：1980年至2043年1G到6G的发展与进步
• 三张资讯图表：6G 在陆地、水和空气上的实际应用、低损耗和热需求
• 6G演进预测
• 非金属扩大份额
• 反对 6G 的争论
• 目前已知的6G通讯的SWOT评估
• 传输距离困境：需要在功率、热和电介质方面取得进步
• 绿化困境：对材料的影响
• 20 种新兴无机化合物在潜在 6G 通讯中的 14 种应用
• 潜在 6G 通讯中 10 个元素的 14 种用途
• 6 个新兴有机家族在潜在 6G 通讯中的 14 种应用
• 摘要
• 6G高附加价值材料製造技术
• 6G 通讯材料和组件机会的 SWOT 评估

第 3 章 6G 低损耗材料及应用

• 6G 低损耗材料：定义、需求、选择
• 5G、6G低损耗材料选择的重大变化
• 6G 的不同介电需求与选项
• 19 个介电常数为 0.1 至 1 THz 的介电族
• 0.1 至 1 THz 范围内 16 个电介质系列的耗散因数：概述
• 19 个电介质系列（0.1 至 1 THz）的耗散因数：详细资讯
• 6G研究中主要提到的低损耗和导热材料
• 6G整合低损耗材料的趋势
• 根据形式和应用对 6G 低损耗材料进行妥协
• 正常介电特性与异常介电特性：6G系统应用
• 用于6G基地台和分散式设备的低损耗材料
• 适用于室内和室外 6G 用户端设备的太赫兹波导
• 6G 低损耗材料机会：SWOT 评估

第 4 章 Epsilon 近零 (ENZ) 材料及其在 6G 中的应用

• ENZ的定义与现象
• ENZ材质开发实例

第 5 章 6G 热管理材料与应用：概述

• 6G 对导热材料的需求不断增加：需要进一步创新
• 陆地与空中6G设备的散热问题
• 解决热挑战时的关键考量因素
• 热管理结构
• 6G热材料集成
• 多样化的新热挑战为新供应商创造了新的可能性
• 新型热管：双孔芯、两种石墨烯选项
• 从最新专利中汲取的经验教训：自修復和高性能热界面材料
• 对 6G 通讯热材料机会的 SWOT 评估

第 6 章 6G 智慧型手机、物联网节点和其他客户端设备的热管理材料

• 摘要
• 17 家公司针对三项导热材料标准的目标活动
• 受 6G 影响，2023 年至 2043 年智慧型手机年销售量将达 10 亿部
• 2023年至2043年智慧型手机导热材料将达到100万平方米
• 从 5G 到 6G 智慧型手机和其他客户端设备的过渡以及散热技术的进步
• 6G热界面材料
• WL Gore：隔热材料气凝胶

第 7 章 6G 热管理中的通配符：热超材料、热水凝胶、热电热泵

• 摘要
• 用于6G微电子和太阳能发电被动冷却的热水凝胶
• 用于 6G 设备、基础设施和太阳能发电的热超材料
• 一般太阳能发电的辐射冷却
• 热超材料 - Plasmonics Inc 和 Radi-Cool
• Nano Meta 科技公司
• 6G晶片热电温控
• 无毒热电材料

第 8 章固态冷却

• 固态冷却的定义与必要性
• 固态冷却工具套件
• 11 个主要结论和 5 个资讯图
• 未来固态冷却最需要的化合物
• 12 种固态冷却工作原理与 10 项功能的比较
• 固态冷却研究管道：依主题与技术准备水平
• 新的固态冷却中心
• 固态冷却和过热保护功能和格式
• 热界面材料和其他冷却的未来：透过热传导
• 有机硅导热材料的SWOT评估
• 固态冷却整体状况以及 7 个新版本的 SWOT 评估
• 大量使用和建议不需要的材料：为您提供的机会
• 冷却技术关注度和成熟度的三个曲线：2024 年、2034 年和 2044 年

第 9 章 6G 超材料

• 摘要
• 元原子和图案选项
• 商业、营运、理论和结构方案的比较
• 超材料图案与材料
• 6G所需的六种超材料的形式和范例
• 超表面底漆
• 超曲面
• 超材料的长期整体图景
• 超表面能量收集很可能在 6G 中成为现实
• GHz、THz、红外线和光学超材料
• 超材料和超表面的整体 SWOT 评估

Summary

6G Communications will bring huge benefits as long the challenges are solved. New low loss and thermal solutions are an essential part of this.

Dr. Peter Harrop, CEO of analysts Zhar Research says, "A market of over $10 billion awaits you if you solve its needs for better low loss and thermal materials and structures for 6G. These opportunities arrive mostly from higher frequencies, more power-hungry, hotter infrastructure and smaller client devices."

The commercially-oriented 318-page Zhar Research report, "6G Communications Low Loss and Thermal Materials and Structures: Detailed Technology Analysis, Roadmaps and 32 Market Forecast Lines 2024-2044" is your essential roadmap. The authors recommend that you consider both topics together because many of your potential partners, competitors and research sources are involved in both. Indeed, some emerging materials such aerogel silicas have uses for both purposes. No other report is as thorough, insightful or up-to-date on the two subjects. The information is constantly updated so you only get the latest.

Questions answered include:

• Winning and losing chemistries and companies?
• Potential partners, acquisitions and emerging competition?
• 20-year roadmaps of decision making, technical capability, adoption?
• Gaps in the market. The unsolved problems that are your opportunities?
• Phase One and Phase 2 evolution of 6G with materials, frequencies, functionality?
• Thirty-two 20-year forecasts of 6G low loss and thermal materials and their hosts?
• Preferred compounds, morphologies, devices, frequencies, active regions emerging?

The analysis is mainly presented as new timelines, infograms, SWOT appraisals, graphs, tables, 20-year forecasts and roadmaps. No nostalgia or academic obscurity but a wealth of latest research papers appraised and much further reading referenced for you to dig deeper if you wish.

The Executive Summary and Conclusions is sufficient in itself if your time is limited. It has 30 pages of choices, trends, possibilities, impediments, SWOT appraisals and technology comparisons and 20 primary conclusions. All the forecasts and roadmaps are in the 27 following pages, each as both tables and graphs with commentary.

Chapter 2 Introduction takes 38 pages to critically explain the 6G dream and reality and introduce a large number of the materials and the manufacturing technologies involved.

Chapter 3 at 58 pages is a core chapter of the report. Entitled, "Low loss materials and applications for 6G" It starts by explaining the important parameters for 6G dielectrics at device, board, package and reconfigurable intelligent surface RIS level. Understand the major changes in low-loss material choices from 5G to 6G. Here are thermoset vs thermoplastic vs inorganic compounds and the special cases of high resistivity silicon, phase change and electric-sensitive dielectrics for the arriving 6G THz frequencies and reasons for the increasing variety of dielectrics needed for 6G. Understand basic mechanisms affecting THz permittivity and seeking low loss through composites and porosity.

Permittivity 0.1-1THz for 19 dielectric families is displayed and compared plus dissipation factor 0.1-1THz for 16 dielectric families. The loss-frequency map is distilled into a choice of 14 families of low permittivity, low loss dielectrics for 6G against 5 criteria followed by detail. Infograms pull together the primary mentions of low loss and thermal materials in 6G research, the trend to integrated low loss materials for 6G and compromises with 6G low loss materials depending on format and application. They include, for example, polyphenylene oxide PPO, PPE, Noryl™ and why silica is one of the most popular porous options for 6G.

Understand low loss materials for 6G base stations and distributed equipment and the implications from traditional base station becoming ultra massive MIMO (UM-MIMO) for 6G even meta-radomes, low loss materials for reprogrammable intelligent surfaces in the propagation path and THz waveguides for 6G client devices, rooms and outdoors. Finally comes a SWOT appraisal of 6G low loss material opportunities. The nine-page Chapter 4. "Epsilon near zero ENZ materials and applications for 6G" explains that aspect.

Now comes a very comprehensive look at thermal materials for 6G. It starts with chapters on thermally conductive structure such as thermal interface materials and heat spreaders, depending on direction of heat dissipation because these are the largest commercial opportunity. In addition, evaporative, radiative and active and passive solid-state cooling and thermal insulation solutions are presented from the research pipeline and best practice for 6G applications.

46-page Chapter 5 opens the thermal material examination with "6G thermal management materials and applications: the big picture". That is brought alive with 24-page Chapter 6. "Thermal management materials for 6G smartphones, IOT nodes and other client devices" followed by a speculative 18-page Chapter 7, "Wild cards for 6G thermal management: thermal metamaterial, thermal hydrogel, thermoelectric heat pump". 17-page Chapter 8 concerns, "Solid state cooling" primarily meaning powered and unpowered smart materials that cool by being responsive and often multi-mode in function. This is because we believe that these should be more seriously considered by 6G developers, for example faced with at least ten times the power consumption and cooling requirement of 6G base stations compared to 5G. The report closes with 17 pages of Chapter 9 on, "Metamaterials for 6G communications" because these are involved in thermal management and other aspects.

The new report, "6G Communications Low Loss and Thermal Materials and Structures: Detailed Technology Analysis, Roadmaps and 32 Market Forecast Lines 2024-2044" is essential reading for materials and subsystem suppliers and investors and it has much to interest product integrators, equipment manufacturers, and others in the 6G supply chain.

CAPTION Low loss materials for 6G systems vs client devices $ billion 2024-2044. Source, "6G Communications Low Loss and Thermal Materials and Structures: Detailed Technology Analysis, Roadmaps and 32 Market Forecast Lines 2024-2044".

Table of Contents

1. Executive Summary and Conclusions with 32 market forecast lines 2024-2044

• 1.1. Purpose of this report
• 1.2. Methodology of this analysis
• 1.3. 20 primary conclusions with 3 infograms
• 1.4. Examples of winning and losing 6G low loss, thermal materials and 6G frequencies
• 1.5. Organisations developing 6G hardware and likely purchasers
• 1.6. How material needs change with 6G communications
  • 1.6.1. Effect of changing network structure
  • 1.6.2. Prevalence of low loss and thermal materials in 6G research by formulation
• 1.7. The quest for 6G low loss materials
  • 1.7.1. Basic mechanisms affecting THz permittivity are challenging at 6G frequencies
  • 1.7.2. THz dielectric permittivity for 19 compounds simplified
  • 1.7.3. Dissipation factor across THz frequency for 16 material families: the big picture
  • 1.7.4. Choice of 14 families of low permittivity, low loss dielectrics for 6G vs five criteria
  • 1.7.5. Seeking low loss through composites and porosity
  • 1.7.6. THz dissipation factor variation for 19 material families: the detail
  • 1.7.7. SWOT appraisal of 6G low loss material opportunities
• 1.8. The quest for 6G thermal materials
  • 1.8.1. Changing balance of needs
  • 1.8.2. Incremental and disruptive opportunities for 6G thermal materials
  • 1.8.3. Comparison of thermal categories against locations, 5G and 6G needs
  • 1.8.4. Seven thermal material attributes against nine physical options
  • 1.8.5. Infographic: base station thermal issues and latest proposals
  • 1.8.6. Here come energy harvesting thermal needs
  • 1.8.7. SWOT appraisal of 6G Communications thermal material opportunities
• 1.9. Technology roadmaps 2024-2044 and 32 market forecast lines 2024-2044
  • 1.9.1. Assumptions
  • 1.9.2. 6G general roadmap by six categories 2024-2044
  • 1.9.3. 6G RIS roadmap 2024-2044
• 1.10. Market forecasts for 6G low-loss and thermal materials in 14 lines 2024-2044
  • 1.10.1. Low loss materials for 6G systems vs devices $ billion 2024-2044
  • 1.10.2. Low loss materials for 6G devices area million square meters 2024-2044
  • 1.10.3. Low loss materials for 6G value market % by frequency in two categories 2029-2044
  • 1.10.4. Low loss and thermal materials for 6G value market % by location 2029-2044
  • 1.10.5. Thermal management material and structure for 6G Communications infrastructure and client devices $ billion 2024-2044
  • 1.10.6. 5G and 6G thermal interface material market $ billion 2024-2044
  • 1.10.7. Smartphone thermal materials market area million square meters 2023-2043
  • 1.10.8. 6G base stations thermal interface materials million square meters 2024-2044
• 1.11. Background forecasts in 18 lines 2024-2044
  • 1.11.1. Total thermal interface material market $ billion 2024-2044
  • 1.11.2. Smartphone units sold globally 2023-2044 if 6G is successful
  • 1.11.3. 6G RIS market by four parameters 2024-2044
  • 1.11.4. Market for 6G vs 5G base stations units millions yearly 3 categories 2024-2044
  • 1.11.5. X-Reality hardware market with possible 6G impact $ billion 2024-2044
  • 1.11.6. Fiber optic cable market global with possible 6G impact $billion 2024-2044
  • 1.11.7. Global metamaterial/ metasurface market by five parameters 2024-2044
  • 1.11.8. Terahertz hardware market excluding 6G $ billion globally 2024-2044
  • 1.11.9. Internet of Things nodes number billion 2024-2044
• 1.12. Location of primary 6G material and component activity worldwide

2. Introduction

• 2.1. Why we need 6G
• 2.2. Disruptive 6G aspects
• 2.3. Widening list of 6G aspirations - impact on hardware
• 2.4. Predictions of NTTDoCoMo, Huawei, Samsung, Nokia and current status
• 2.5. 6G standards procedure settled
• 2.6. Infogram: Progress from 1G-6G rollouts 1980-2043
• 2.7. Three infograms: 6G in action land, water, air and low loss and thermal needs
• 2.8. Likely 6G evolution
• 2.9. Non-metals gain share
• 2.10. The arguments against 6G
• 2.11. SWOT appraisal of 6G Communications as currently understood
• 2.12. Transmission distance dilemma calls for power, thermal and dielectric advances
• 2.13. The going green dilemma - impact on materials
• 2.14. 14 applications of 20 emerging inorganic compounds in potential 6G communications
• 2.15. 14 applications of 10 elements in potential 6G communications
• 2.16. 14 applications of 6 emerging organic families in potential 6G communications
• 2.17. Roundup
• 2.18. Manufacturing technologies for 6G high added value materials
  • 2.18.1. Reel to reel by technology
  • 2.18.2. Thermal material manufacturing for 6G
  • 2.18.3. New thermal interface material TIM manufacturing technology in 2022
  • 2.18.4. New heat spreader manufacturing technology in 2022
• 2.19. SWOT appraisal of 6G Communications material and component opportunities

3. Low loss materials and applications for 6G

• 3.1. Definition, requirements and choices for 6G low-loss materials
  • 3.1.1. Overview
  • 3.1.2. Important parameters for 6G dielectrics at device, board, package and RIS level
  • 3.1.3. Thermoset vs thermoplastic vs inorganic compounds
  • 3.1.4. Special case: high resistivity silicon for THz frequencies
  • 3.1.5. Special cases: phase change and electric-sensitive dielectrics for 6G
• 3.2. Major changes in low-loss material choices from 5G to 6G
  • 3.2.1. Infogram: Changes from 5G to 6G: better parameters, lower costs, larger areas
  • 3.2.2. Low loss materials adoption for 3G, 4G, 5G
• 3.3. Different dielectric needs and choices for 6G
  • 3.3.1. Compared to 5G
  • 3.3.2. Reasons for the increasing variety of dielectrics needed for 6G
  • 3.3.3. Basic mechanisms affecting THz permittivity are challenging at 6G frequencies
  • 3.3.4. Seeking low loss through composites and porosity
• 3.4. Permittivity 0.1-1THz for 19 dielectric families
• 3.5. Dissipation factor 0.1-1THz for 16 dielectric families: the big picture
  • 3.5.1. The loss-frequency map explained
  • 3.5.2. Choice of 14 families of low permittivity, low loss dielectrics for 6G against 5 criteria
• 3.6. Dissipation factor 0.1-1THz for 19 dielectric families: the detail
• 3.7. Primary mentions of low loss and thermal materials in 6G research
• 3.8. Trend to integrated low loss materials for 6G
• 3.9. Compromises with 6G low loss materials depending on format and application
• 3.10. Routine and unusual dielectrics have applications in 6G systems
  • 3.10.1. Polyphenylene oxide PPO,PPE and Noryl™
  • 3.10.2. Why silica is one of the most popular porous options for 6G
• 3.11. Low loss materials for 6G base stations and distributed equipment
  • 3.11.1. Overview and the dielectric waveguide option
  • 3.11.2. Traditional base station becomes ultra massive MIMO = UM-MIMO for 6G
  • 3.11.3. Metaradomes
  • 3.11.4. Low loss materials for reprogrammable intelligent surfaces
• 3.12. THz waveguides for 6G client devices, rooms and outdoors
• 3.13. SWOT appraisal of 6G low loss material opportunities

4. Epsilon near zero ENZ materials and applications for 6G

• 4.1. ENZ definition and phenomena
  • 4.1.1. Contrast with low-loss materials covered in Chapter 3
  • 4.1.2. ENZ definition
  • 4.1.3. Unfamiliar functions of familiar materials
  • 4.1.4. Magical functions useful for what?
• 4.2. Examples of ENZ material development

5. 6G thermal management materials and applications: the big picture

• 5.1. Greater need for thermal materials in 6G demands more innovation
• 5.2. Thermal issues with 6G equipment on land and in the air
  • 5.2.1. Overview
  • 5.2.2. Thermal issues with 6G infrastructure on land
  • 5.2.3. Infogram: Base station thermal issues and latest proposals
  • 5.2.4. Large battery thermal management for 6G
  • 5.2.5. Extra thermal management challenges
  • 5.2.6. Future needs and trends for 6G devices up to MW power provision for 6G
• 5.3. Important considerations when solving thermal challenges
  • 5.3.1. Bonding or non-bonding
  • 5.3.2. Varying heat
  • 5.3.3. Placement
  • 5.3.4. Environmental attack
• 5.4. Heat management structures
  • 5.4.1. Learning from 5G
  • 5.4.2. Choosing a thermal structure
  • 5.4.3. Research on embedded cooling
• 5.5. Integration of 6G thermal materials
• 5.6. Diverse new thermal challenges emerging allow in new suppliers
  • 5.6.1. Overview
  • 5.6.2. Water-cooled photovoltaics for heating and electricity: Sunovate
  • 5.6.3. Thermally conductive concrete for on-site 6G power transmission: Heidelberg
  • 5.6.4. Thermoelectrics for 6G temperature control and electricity: Gentherm
  • 5.6.5. Thermoradiative photovoltaics: Stanford
  • 5.6.6. THz thermal switching of vanadium-dioxide-embedded metamaterials for 6G RIS
  • 5.6.7. Thermally switched chalcogenide phase change materials for 6G RIS
  • 5.6.8. Materials for thermal infrared and other photovoltaics: Sharp, Spectrolab, SolAero
  • 5.6.9. Reconfigurable intelligent surface thermal management for 6G
• 5.7. New heat pipes in 2021 and 2022: biporous wick, two graphene options
• 5.8. Lessons from latest patents: self-repairing and better performing thermal interface material
• 5.9. SWOT appraisal of 6G Communications thermal materials opportunities

6. Thermal management materials for 6G smartphones, IOT nodes and other client devices

• 6.1. Overview
• 6.2. Targetted activity of 17 companies against 3 thermal material criteria
• 6.3. Smartphones billion yearly 2023-2043 with 6G impact
• 6.4. Smartphone thermal materials market area million square meters 2023-2043
• 6.5. Thermal progress from 5G to 6G smartphones and other client devices
  • 6.5.1. Thermal management locations for 6G smartphones and other client devices
  • 6.5.2. Thermal conductors currently: Henkel, ShinEtsu, Sekisui, Fujitsu, Suzhou Dasen
  • 6.5.3. Microscale heat pipes
• 6.6. Thermal interface materials for 6G
  • 6.6.1. Seven current options compared against nine parameters
  • 6.6.2. Thermal pastes compared for 6G devices
  • 6.6.3. Trending: phase change materials
  • 6.6.4. Trending: annealed pyrolytic graphite
• 6.7. Thermal insulation internally aerogel WL Gore
  • 6.7.2. Thermal insulation to protect smartphones from the sun and cold
  • 6.7.3. other companies involved in silica aerogel insulation

7. Wild cards for 6G thermal management: thermal metamaterial, thermal hydrogel, thermoelectric heat pump

• 7.1. Overview
• 7.2. Thermal hydrogels for passive cooling of 6G microelectronics and photovoltaics
• 7.3. Thermal metamaterials for 6G devices, infrastructure and photovoltaics
• 7.4. Radiative cooling of photovoltaics generally
• 7.5. Thermal metamaterial - Plasmonics Inc and Radi-Cool
• 7.6. Nano Meta technologies Inc.
• 7.7. Thermoelectric temperature control for 6G chips
• 7.8. Non-toxic thermoelectrics

8. Solid state cooling

• 8.1. Definition and need for solid-state cooling
• 8.2. Solid state cooling toolkit
• 8.3. Eleven primary conclusions with five infographics
• 8.4. The most needed compounds for future solid-state cooling
• 8.5. Twelve solid-state cooling operating principles compared by 10 capabilities
• 8.6. Research pipeline of solid-state cooling by topic vs technology readiness level
• 8.7. Heart of emerging solid-state cooling
• 8.8. Function and format of solid-state cooling and prevention of heating
• 8.9. The future of thermal interface materials and other cooling by thermal conduction
• 8.10. SWOT appraisal for silicone thermal conduction materials
• 8.11. SWOT appraisals of solid-state cooling in general and seven emerging versions
• 8.12. SWOT appraisal of Passive Daytime Radiative Cooling PDRC
• 8.13. SWOT appraisal of self-cooling radiative metafabric
• 8.14. SWOT appraisal of Anti-Stokes fluorescent cooling
• 8.15. SWOT appraisal of electrocaloric cooling and thermal management
• 8.16. SWOT appraisal of magnetocaloric cooling
• 8.17. SWOT appraisal of mechanocaloric cooling
• 8.18. SWOT appraisal of thermoelectric cooling and temperature control
• 8.19. Undesirable materials widely used and proposed: this is an opportunity for you
• 8.20. Attention vs maturity of cooling technologies 3 curves 2024, 2034, 2044

9. Metamaterials for 6G applications

• 9.1. Overview
• 9.2. The meta-atom and patterning options
• 9.3. Commercial, operational, theoretical, structural options compared
• 9.4. Metamaterial patterns and materials
• 9.5. Six formats of metamaterial needed for 6G with examples
• 9.6. Metasurface primer
• 9.7. Hypersurfaces
• 9.8. The long-term picture of metamaterials overall
• 9.9. Metasurface energy harvesting likely for 6G
• 9.10. GHz, THz, infrared and optical metamaterials
• 9.11. SWOT assessments for metamaterials and metasurfaces generally