Summary
この調査レポートは、世界のエアロゲル市場について包括的かつ権威ある見解を提供し、用途別、材料の種類と形態別に区分した10年間の詳細な市場予測を掲載しています。
主な掲載内容(目次より抜粋)
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エアロゲル
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市場概要と予測
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シリカエアロゲル製品
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有機エアロゲル製品
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立法政策と資金援助
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EVバッテリーの防火材料としてのエアロゲル
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エアロゲルのその他の用途
Report Summary
This market report provides a comprehensive and authoritative view of the global aerogel market, giving detailed ten-year market forecasts segmented by application and both material type and form. IDTechEx has been studying the aerogel industry for many years with technical experts conducting an extensive number of primary interviews to bring the reader a granular and detailed assessment of this industry.
Aerogels have experienced steady market growth historically, reaching a market of just under US$450 million in 2022. Progress has been somewhat slower than some would expect, this has largely been due to competition with lower cost incumbent insulation materials. However, the emergence of aerogels as a fire protection material for electric vehicle (EV) batteries provides a new and rapidly growing opportunity for the aerogel market. IDTechEx predicts that this will be the dominant application for aerogels within the forecast period.
IDTechEx predicts that EV batteries will be the dominant application for aerogels in the future. Source: IDTechEx
The report provides benchmarking of aerogels against other fire protection materials for EV battery packs. The thermal insulation, compression, and fire protection benefits that aerogels can provide, along with their low density, means they are starting to see much greater adoption in this application. Whilst much of this progress has been in China, other regions are getting involved, for example, GM selected Aspen Aerogels' products for its Ultium platform.
A detailed assessment of all the aerogel manufacturers is given in the report, including their capacity, revenue, products, production processes, planned expansions, and more. A comprehensive patent analysis is conducted, which looks at key assignees and applications.
This report also details and benchmarks the different types and forms of pure and composite aerogel products. The most prevalent of these is silica aerogels, with the key property being very low thermal conductivity (λ = 15-25 mW/m.K); the commercial applications to date centre almost exclusively around silica blankets and panels for their use in thermal insulation. However, given the abundance and cost of traditional insulators, manufacturers have been unable to justify the high price on the superior insulating properties alone. Instead, they have looked to the added value of the properties these multi-functional materials possess, be it fire retardancy, low density, hydrophobicity, strength or electrical/acoustic insulation.
Silica particles (granules and powders) are gaining an increasing amount of interest either integrated into blankets and sheets post-production or used as fillers in a range of liquid or solid products including coatings, daylighting panels, and building material. Cabot Corporation has remained as the key player in these high-performance particles for over two-decades and continues to have its material implemented into new markets. Alongside this is the rise of the lower cost powders, led by the likes of JIOS Aerogel, that are gaining some market traction.
IDTechEx has identified organic aerogels, notably polymer panels and films, as a rapidly emerging area of commercial activity. Although silica monoliths are the most photographed, their brittleness makes them have practically no commercial applications. Polymer variants have very different mechanical properties, taking the industry in many new directions. Many of the promising players are establishing notable production capacities and there is already significant interest from large end-users across a range of sectors for their use in antennas to interiors for transportation. Carbon aerogels have been known for a longer time but are again seeing lots of market activity and technology developments (such as graphene aerogels) showing the most promise for energy storage applications.
Finally, this report looks further into the future, describing the cutting-edge applications and manufacturing techniques. Pricing forecasts are provided for all different types and are predicted to undergo significant shifts as increased capacities and emerging manufacturing processes are anticipated. The report extensively compares and discusses batch and continuous manufacturing processes for both supercritical drying, freeze drying, and ambient pressure drying techniques. This is with consideration to both established methods, start-up companies, and relevant academic or industrial research. There remains a constant interest in new materials, utilising renewable or recycled feedstocks, and ambitious manufacturing techniques such as 3D printing.
Key aspects
Benchmarking of aerogel products:
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Thermal conductivity
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Density
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Applications and maturity
Analysis of aerogel applications:
Electric vehicle batteries, oil and gas, industrial, building and construction, windows, apparel, cosmetics, transportation, energy storage, aerospace, and several others
10 year market forecasts in US$:
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Aerogel type: silica, carbon and polymer aerogels
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Aerogel applications: EV Battery, industrial (including refineries), LNG, building and construction, energy infrastructure, apparel, footwear, and sport, cosmetics, electronics, windows, and other
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Aerogels as fire protection in EV battery packs: inter-cell and pack-level
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Polymer and carbon aerogels by application: eVTOL/eCTOL and other
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Table of Contents
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1. |
EXECUTIVE SUMMARY |
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1.1. |
EV Battery Packs are the Application Aerogels Needed |
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1.2. |
Thermal Runaway and Fires in EVs |
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1.3. |
Growing EV Market |
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1.4. |
Regional EV Battery Safety Standards Overview |
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1.5. |
Main Categories of Fire Protection Materials |
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1.6. |
Fire Protection Materials Comparison |
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1.7. |
Density vs Thermal Conductivity - Thermally Insulating Fire Protection for EVs |
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1.8. |
Material Intensity in EV Batteries (kg/kWh) |
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1.9. |
Aerogels Forecast for EV Battery Fire Protection 2020-2034 (US$) |
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1.10. |
Forecast by Aerogel Application 2020-2034 (US$) |
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1.11. |
Aerogel Thermal Conductivity Benchmarking Study 2023 |
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1.12. |
Forecast by Aerogel Form and Type 2020-2034 (US$) |
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1.13. |
Silica Aerogel Properties |
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1.14. |
Different Forms of Aerogels |
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1.15. |
Capacity of Aerogel Manufacturers and Expansions |
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1.16. |
Aerogels Manufacturer Revenues 2020, 2022 |
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1.17. |
Aerogel Manufacturing Process by Player in 2023 |
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1.18. |
China Dominates Aerogel Manufacturing but Less So for Revenue (2022) |
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1.19. |
Carbon and Polymer Aerogel Forecast 2020-2034 (US$) |
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2. |
INTRODUCTION TO AEROGELS |
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2.1. |
What is an aerogel? |
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2.2. |
How are aerogels made? |
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2.3. |
A brief history of aerogels |
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2.4. |
Supercritical drying process: overview |
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2.5. |
Supercritical drying process: closed loop |
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2.6. |
Supercritical drying process: autoclave loading |
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2.7. |
Supercritical drying advancements |
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2.8. |
Ambient pressure drying process - Cabot Corporation |
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2.9. |
Aerogel Manufacturing Process by Player in 2023 |
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2.10. |
Silica Aerogel Properties |
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2.11. |
Different Forms of Aerogels |
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2.12. |
Silica aerogel properties by pure form |
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2.13. |
Aerogel Thermal Conductivity Benchmarking Study 2023 |
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2.14. |
Aerogel Thermal Conductivity and Density Benchmarking Study 2023 |
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2.15. |
Quantitative benchmarking study - Measurement Accuracy |
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2.16. |
Advanced silica aerogel properties |
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2.17. |
Silica aerogel precursors |
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2.18. |
Aerogel tree by type |
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3. |
MARKET OVERVIEW AND FORECAST |
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3.1. |
Comprehensive company list, capacity and 2023 status |
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3.2. |
Comprehensive company list, capacity and status |
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3.3. |
Aerogel Company Founding Date Comparison |
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3.4. |
Development of supercritical aerogel manufacturing processes |
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3.5. |
Hype curve of aerogel by application |
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3.6. |
Patent infringement news and outlook |
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3.7. |
Aerogel patent analysis: main players |
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3.8. |
Aerogel google trends |
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3.9. |
Aerogel patent analysis: application spikes |
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3.10. |
Market Forecast Information and Overview |
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3.11. |
Market Forecast By Industry Sector |
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3.12. |
Forecast by Aerogel Form and Type 2020-2034 (US$) |
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3.13. |
Revenue of aerogel manufacturers |
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3.14. |
Capacity of aerogel manufacturers |
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3.15. |
Upcoming notable capacity expansions, 2023 onwards |
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3.16. |
Chinese manufacturers - 2023 region, status, and outlook |
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3.17. |
China Dominates Aerogel Manufacturing but Less So for Revenue (2022) |
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3.18. |
e-commerce sites for aerogels |
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3.19. |
Market leaders overview: Aspen Aerogels |
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3.20. |
Market leaders overview: Aspen Aerogels (2) |
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3.21. |
Market leaders overview: Cabot Corporation |
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3.22. |
Cabot's Line for EV Battery Applications |
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3.23. |
Recent Progress and Applications in China |
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3.24. |
New Entrants in China |
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3.25. |
New Insulation Applications in China |
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3.26. |
Other New Applications in China |
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3.27. |
Carbon Aerogel Applications in China |
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3.28. |
Aerogels - New Entrants and Applications in China |
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4. |
SILICA AEROGEL PRODUCTS |
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4.1. |
Silica composite aerogels - matrix reinforced. Aspen Aerogel products |
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4.2. |
Silica composite aerogels - matrix reinforced. Aspen Aerogel manufacturing |
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4.3. |
Silica composite aerogels - cost analysis |
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4.4. |
Silica composite aerogels - composites formed from powders and granules |
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4.5. |
Silica composite aerogels - Armacell and JIOS Aerogel Partnership |
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4.6. |
Silica composite aerogels - Armacell 2023 developments |
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4.7. |
Silica composite aerogels formed from powder and granules - players and progress |
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4.8. |
Research into opacifying composite silica aerogel |
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4.9. |
Silica composite aerogels - Huntsman and Cabot Corporation case study |
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4.10. |
Powder aerogel SWOT analysis |
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4.11. |
Granule aerogel SWOT analysis |
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4.12. |
"Aerogel-like" products |
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4.13. |
"Aerogel-like" products - SUMTEQ |
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4.14. |
Silica aerogel in end-user liquid products |
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4.15. |
Silica Aerogel powder manufacturing processes |
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4.16. |
Cost optimised ambient pressure drying process - university research |
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4.17. |
Powders and granules prepared under ambient pressure - university research |
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4.18. |
Organic crosslinkers |
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4.19. |
Organic crosslinkers (2) |
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4.20. |
Monolith prepared under ambient pressure |
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4.21. |
Rapid supercritical extraction |
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4.22. |
3D printing of aerogels |
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4.23. |
3D printing of aerogels (2) |
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4.24. |
Alternative monolithic aerogel manufacturing processes - university research |
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4.25. |
Cost progression for powder and granule silica aerogels |
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4.26. |
Market share for silica granule and powder manufacturers |
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4.27. |
Silica aerogel from sustainable feedstocks |
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4.28. |
Silica aerogel from sustainable feedstocks (2) |
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5. |
ORGANIC AEROGEL PRODUCTS |
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5.1. |
Polymer aerogels - introduction |
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5.2. |
Polymer aerogels - Aerogel Technologies |
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5.3. |
Polymer aerogels - Blueshift Materials |
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5.4. |
Polymer aerogels - aerogel-it |
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5.5. |
Polymer aerogels - IBIH |
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5.6. |
Research into polymer aerogels |
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5.7. |
Research into polymer aerogels - NASA |
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5.8. |
Polymer aerogels used alongside graphene |
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5.9. |
Carbon aerogel - manufacturing and properties |
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5.10. |
Key carbon aerogel manufacturers |
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5.11. |
Research into carbon aerogels |
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5.12. |
Graphene and graphite aerogel |
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5.13. |
Graphene and graphite aerogel (2) - Aerogel Core Ltd |
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5.14. |
Graphene and graphite aerogel (3) |
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5.15. |
3D Printing of organic aerogels - carbon and graphene |
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5.16. |
Aerogels used alongside graphene |
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5.17. |
Sustainable aerogel - natural sources |
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5.18. |
Sustainable aerogel - natural sources (2) |
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5.19. |
Sustainable aerogel - waste material |
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5.20. |
Carbon and Polymer Aerogel Application Forecast 2020-2034 (US$) |
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5.21. |
Carbon and Polymer Aerogel Forecast 2020-2034 (US$) |
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IDTechEx社の先端材料 - Advanced Materials分野での最新刊レポート
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