How can we deal with the increasing problems of thermal management with every new generation of wireless communications? We get ever more infrastructure generating more heat and more compact client devices offering less space for thermal management. The new 533-page, commercially-oriented Zhar Research report, "6G Communications Thermal Materials for Infrastructure and Client Devices: Opportunities, Markets, Technology 2026-2046" has the answers and forecasts the large market, mainly for new cooling materials, that will emerge.
Incremental then disruptive
Dr. Peter Harrop, CEO of Zhar Research, puts it this way. "Initially, 6G will be an incremental improvement mainly using, and limited by, 5G frequencies and largely served by improved 5G thermal solutions. Ubiquity is a top priority for 6G. No more patchy coverage in cities from London to Tokyo and dead in the countryside and ocean. Much more self-powering, thermally managed, will avoid the considerable cost of running power to expanding terrestrial infrastructure and the impossibility of running power to burgeoning aerospace infrastructure for 6G. However, 6G Phase Two, around 2035, must be a whole new ball game to achieve real financial success with startlingly better performance and reach. That means disruptive new thermal solutions for everything from active, transparent, 360-degree reconfigurable intelligent surfaces to reinvented, "must have" personal electronics."
Detailed analysis required beyond 6G, with latest research prioritised
He points out that, to meet the thermal challenges, including in more compact client devices in huge numbers, such as things-collaborating-with-things, we must benchmark best practice far beyond telecommunications today. Indeed, as base stations sometimes vanish into multipurpose high-rise buildings and stratospheric solar drones and as client devices vanish into wearables, implants and more, thermal management uniquely for 6G will become less common. The report finds great opportunities for new thermal materials and principles in all this. Necessarily, the report is very detailed, involving 11 chapters, 11 SWOT appraisals, 32 forecast lines 2026-2046 and 33 new infograms. Vitally, it analyses the flood of new research advances through 2025 because out-of-date reports can be very misleading in this rapidly evolving subject. Indeed, the report is continuously updated so you only get the latest.
Quick read
The 48-page Executive Summary and Conclusions is sufficient for those with limited time. See the emerging needs, 19 primary conclusions, detailed 20-year roadmaps in 6 lines and those 32 forecasts with explanation, for example. The radically new cooling technologies such as Passive Daylight Radiative Cooling PDRC, five forms of caloric cooling and wide-area thermoelectrics are introduced together with combinations. See why solid-state cooling comes to the fore. A pie chart prioritises solid-state-cooling materials in number of latest research advances, revealing some issues with toxigens, for this report is unbiassed. Parameter comparisons and forecasts of their improvement are presented.
Tougher and more varied thermal needs arriving
Chapter 2. Introduction (40 pages) explains the changing view of what 6G seeks to achieve and when and the trend to smart thermal materials to assist. From graphics, quickly absorb the severe new microchip cooling requirements arriving, cooling 6G electronic components, smartphones and 6G base stations including cooling solar panels and cladding for 6G infrastructure, and thermal management of large batteries for 6G infrastructure. There are hype curves for the thermal materials by year ahead, and a table where twelve solid-state cooling operating principles are compared by 10 capabilities. See examples of advances in 2024-5. Indeed, every chapter examines latest advances.
New approaches to cooling arriving and eagerly sought
Cooling that does not need power will be as important as self-powered infrastructure in avoiding prohibitive costs for vast 6G infrastructure everywhere. Therefore Chapter 2 covers Passive Daytime Radiative Cooling (PDRC) ejecting heat from Earth through the near-infrared window. Understand 40 important advances in 2024-5 and how ten companies are commercialising PDRC. 103 pages are needed due to the wide relevance to 6G, from enhancing its thermoelectric energy harvesting to cooling base stations and buildings. Three SWOT appraisals respectively address passive radiative cooling in general, Janus effect for thermal management and anti-Stokes thermal management.
Ferroic cooling will become important
Chapter 5. Phase Change and Particularly Caloric Cooling shows how the conventional phase changes between gas, liquid and solid have limited relevance to 6G but ferroic phase change called caloric cooling could be very valuable. Learn which forms are most promising and what research achieved through 2025. The 77 pages present pie charts, SWOT appraisals and tables pulling it all together.
Thermoelectrics reinvented
Chapter 7, in 53 pages, covers future thermoelectric cooling such as wide area versions. Thermoelectric harvesting for 6G "Zero emission devices ZED" also appears. Its cold side is becoming a user of new forms of solid-state cooling and it can power active forms of solid-state cooling, all applicable to 6G Communications. There is even analysis of new research on multifunctional cooling and multi-mode cooling, both including thermoelectrics as a part because 6G thermal management must become much more sophisticated, such are the challenges it must address.
Evaporative, melting and flow cooling
Chapter 8. takes 38 pages to cover future evaporative, melting and flow cooling including heat pipes, new thermal hydrogels for 6G client devices and infrastructure. Infograms, commentary and comparisons make sense of it all. Chapter 9 then takes 57 pages to analyse Thermal Interface Materials TIM and other emerging materials for 6G conductive cooling challenges. Then Chapter 10 (30 pages) covers advanced heat shielding, thermal insulation and new ionogels for 6G and Chapter 11 (26 pages) gives the big picture of thermal metamaterials for benchmarking into 6G. All these chapters include much 2025 research.
Unique, essential reference
This Zhar Research report, "6G Communications Thermal Materials for Infrastructure and Client Devices: Opportunities, Markets, Technology 2026-2046" is your essential up-to-date and in-depth source as you participate in the lucrative new 6G thermal materials market that is emerging. Product and system integrators and operators will also value the report.
CAPTION: Dielectric and thermal materials for 6G value market % by location 2029-2046. Source Zhar Research report, "6G Communications Thermal Materials for Infrastructure and Client Devices: Opportunities, Markets, Technology 2026-2046".
Table of Contents
1. Executive summary and conclusions
1.1. Purpose of this report and assumptions
1.2. Methodology of this analysis
1.3. SWOT appraisal of 6G Communications thermal material opportunities
1.4. Some reasons for the escalating need for cooling
1.5. Cooling toolkit, trend to multifunctionality with best solid-state cooling tools shown red
1.6. The nature of solid-state cooling and why it is now a priority for 6G and generally
1.7. Primary conclusions: 6G thermal requirements
1.8. Primary conclusions: Materials for making cold in 6G infrastructure and client devices
1.8.1. General situation
1.8.2. Leading candidate materials and structures compared
1.8.3. Leading materials in number of latest research advances on solid state cooling
1.8.4. Research pipeline of solid-state cooling by topic vs technology readiness level
1.8.5. Typical best reported temperature drop achieved by technology 2000-2046 extrapolated
1.8.6. SWOT appraisal of Passive Daytime Radiative Cooling PDRC and pie chart of leading materials
1.8.7. SWOT appraisal of electrocaloric cooling and pie chart of leading materials
1.8.8. SWOT appraisal of elastocaloric cooling and leading materials
1.8.9. SWOT appraisal of thermoelectric cooling and pie chart of leading materials
1.9. Primary conclusions: Materials for removing heat by conduction and convection
1.10. Roadmaps of 6G materials and hardware and separately cooling 2026-2046
1.11. Market forecasts in 32 lines 2026-2046
1.11.1. Thermal management material and structure for 6G infrastructure and client devices $ billion 2026-2046
1.11.2. Dielectric and thermal materials for 6G value market % by location 2029-2046
1.11.3. 5G vs 6G thermal interface material market $ billion 2025-2046
1.12. Background forecasts 2025-2046
1.12.1. Cooling module global market by seven technologies $ billion 2025-2046
1.12.2. Terrestrial radiative cooling performance in commercial products W/sq. m 2025-2046
1.12.3. Market for 6G vs 5G base stations units millions yearly 2025-2046
1.12.4. Market for 6G base stations market value $bn if successful 2025-2046
1.12.5. 6G RIS value market $ billion: active and three semi-passive categories 2029-2046
