Global 6G Communications: Low Loss and Thermal Materials Market Report to 2043 - ResearchAndMarkets.com

DUBLIN--(BUSINESS WIRE)--The "6G Communications: Low Loss and Thermal Materials Markets 2023-2043" report has been added to ResearchAndMarkets.com's offering.

This report finds this is possible from low loss and thermal materials and assemblies for 6G Communications which bursts on the scene in 2030. Expect two phases.

It starts at 0.1-0.3THz with incrementally-improved low loss and thermal materials in a very different mix from that for 5G. They are identified from a close look at the parameters of 19 dielectric families and a similar number of thermal options matched against the new needs. Second phase from around 2035 involves 0.3-1THz capability being added together with high-power infrastructure for driving client devices with no on-board power such as internet of things nodes.

Both call for disruptive change in materials so the report even covers epsilon near zero ENZ dielectric surrogates, metamaterial and hydrogel cooling layers and non-toxic thermoelectric temperature holding. Ultra-massive multiple in multiple out UM-MIMO base stations and active reprogrammable intelligent surfaces RIS require high power photovoltaics on-site also needing low loss and thermal materials. Uniquely, this report covers it all with a host of further reading referenced from an intense look at the latest research pipeline and the basics presented without obscure mathematics.

The report is for added value materials suppliers and users needing clear new analysis without nostalgia or bias. That is why so much is explained in pictures and summaries identifying gaps in the market and commercial opportunity. There is a detailed glossary at the start and terms are also explained throughout. A great deal is presented from 2022 advances and the report is constantly updated so you get the latest - vital with such fast-moving subject.

Questions answered include:

• New low loss and thermal requirements brought by 6G?
• 2023-2043 forecasts of materials and devices with assumptions?
• Current materials that will lose share as 6G arrives: escape routes?
• Likely suppliers, purchasers, new entrants, winning formulations and formats?
• Traditional and new needs and inventions with appraisal of latest research pipeline?

Key Topics Covered:

1. Executive Summary and 11 forecasts 2023-2043

2. Introduction

3. Low loss materials and applications for 6G

3.1 Definition, requirements and choices for 6G low-loss materials

3.2 Major changes in low-loss material choices from 5G to 6G

3.3 Different dielectric needs and choices for 6G

3.4 Permittivity 0.1-1THz for 19 dielectric families

3.5 Dissipation factor 0.1-1THz for 16 dielectric families: the big picture

3.6 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

3.11 Low loss materials for 6G base stations and distributed equipment

3.12 Contrast: the 2022 barium titanate breakthrough

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

4.2 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

5.3 Important considerations when solving thermal challenges

5.4 Heat management structures

5.5 Integration of 6G thermal materials

5.6 Diverse new thermal challenges emerging allow in new suppliers

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

6.6 Thermal interface materials for 6G

6.7 Thermal insulation internally aerogel WL Gore

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. Metamaterials for 6G applications

8.1 Overview

8.2 The meta atom and patterning options

8.3 Commercial, operational, theoretical, structural options compared

8.4 Metamaterial patterns and materials

8.5 Six formats of metamaterial needed for 6G with examples

8.6 Metasurface primer

8.7 Hypersurfaces

8.8 The long term picture of metamaterials overall

8.9 Metasurface energy harvesting likely for 6G

8.10 Applications of GHz, THz, infrared and optical metamaterials

8.11 SWOT assessments for metamaterials and metasurfaces generally

For more information about this report visit https://www.researchandmarkets.com/r/ifjp2