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气凝胶的全球市场(2025年~2035年)
市场调查报告书
商品编码
1661288

气凝胶的全球市场(2025年~2035年)

The Global Aerogels Market 2025-2035
出版日期: | 出版商: Future Markets, Inc. | 英文 208 Pages, 56 Tables, 44 Figures | 订单完成后即时交付

价格
简介目录

全球气凝胶市场已大幅成长,从一种小众特种材料转变为重要的商业领域。这种增长是由气凝胶的优异性能所推动的,例如超低热导率(0.015 W/mK)、极轻重量(80-150 kg/m3)、高孔隙率和阻燃性。二氧化硅气凝胶继续占据主导地位,主要用于石油和天然气、建筑隔热和工业应用。然而,由于聚合物基气凝胶的柔韧性和加工性得到改善,其成长速度正在加速,在运输、服装和航空应用领域越来越有吸引力。碳气凝胶和生物基气凝胶已成为在能源储存、催化和永续材料领域具有专门应用的关键领域。

按地区划分,北美目前占据收入领先地位,但中国正在迅速扩大其製造能力。由于严格的建筑隔热法规和永续发展举措,欧洲市场依然保持强劲。成长最快的应用是电动车电池的热管理,随着製造商采用气凝胶解决方案来防止热失控和火灾,该应用的年增长率超过 40%。竞争格局正在发生重大变化,现有企业不断扩大产能,而广东艾利森和IBIH先进材料等中国製造商正迅速扩大生产规模。专注于小众应用或先进製造方法的小型专业製造商也正在出现。

技术进步至关重要,与传统的超临界方法相比,常压干燥技术降低了生产成本。製造创新(包括连续卷对卷製程)提高了可扩展性,而新的混合方法和复合结构也扩展了其能力。儘管某些应用仍然存在高生产成本和加工课题,但随着製造规模的扩大,这些障碍正在逐渐减少。全球能源效率法规、建筑规范、电动车安全标准和工业脱碳措施等市场推动因素持续加强气凝胶在各领域应用的价值主张。

展望未来,随着生产成本持续下降和新应用的出现,尤其是在交通运输、永续建筑材料、能源储存和高性能工业应用领域,气凝胶市场预计将继续保持强劲成长。整个产业对更轻、更高效材料的追求为气凝胶不断扩大的市场占有率提供了坚实的基础。

本报告提供全球气凝胶市场相关调查,与市场促进因素趋势,生产能力,技术课题,市场预测,专利,企业简介等资讯。

目录

第1章 摘要整理

  • 气凝胶的特性
  • 气凝胶的用途
  • 气凝胶市场上竞争要素
  • 推动市场要素和趋势
  • 气凝胶的厂商和生产能力
  • 市场与技术的课题
  • 市场规模与预测(2021年~2035年)
    • 各气凝胶类型
    • 各市场
    • 各地区

第2章 简介

  • 气凝胶
    • 气凝胶的起源
    • 分类
    • 气凝胶泡沫
    • 市售的气凝胶
  • 二氧化硅气凝胶
    • 特性
    • 产品
    • 成本
    • 主要参与企业
  • 气凝胶类聚合物泡沫
    • 特性
    • 气凝胶类聚合物泡沫的用途中包含以下。
  • 金属氧化物气凝胶
  • 有机气凝胶
    • 聚合物为基础的气凝胶
    • 生物为基础气凝胶(生物气凝胶)
    • 碳气凝胶
  • 3D印刷气凝胶
    • 氮化碳
  • 混合,复合气凝胶
    • 混合氧化物气凝胶
    • 金属氧化物气凝胶复合材料
    • 碳为基础的气凝胶复合材料

第3章 生产方式

  • 概要
  • 溶胶凝胶法
  • 气凝胶的3D列印
  • 干燥法
    • 干燥法概要
    • 超临界干燥
    • 平常压干燥
    • 急速超临界开采(RSCE)
    • 优点和缺点
  • 成本

第4章 气凝胶的市场与用途

  • 竞争情形
  • 石油、天然气
    • 概要
    • 用途
  • 建筑·建设
    • 概要
    • 永续的隔热材料的类型
    • 用途
  • 能源储存
    • 概要
    • 用途
  • 生物医学
    • 概要
    • 用途
  • 低温运输包装
    • 概要
  • 电子,通讯
    • 概要
    • 用途
  • 过滤,分离,吸着
    • 概要
    • 用途
  • 纺织品
    • 概要
    • 用途
  • 食品
    • 概要
  • 催化剂
  • 油漆和涂料
  • 航太·防卫
    • 概要
    • 用途
  • 化妆品
    • 概要
  • 汽车
    • 概要
    • EV电池
  • 其他的市场与用途

第5章 气凝胶的专利

  • 专利申请

第6章 气凝胶企业简介(50公司的企业简介)

第7章 调查范围和调查手法

第8章 参考文献

简介目录

The global aerogel market has experienced remarkable growth, transforming from a niche specialty material into a significant commercial sector. This growth is fueled by aerogels' exceptional properties, including ultra-low thermal conductivity (as low as 0.015 W/m-K), extreme lightweight nature (80-150 kg/m3), high porosity, and fire resistance. Silica aerogels continue to dominate, primarily serving oil and gas, building insulation, and industrial applications. However, polymer-based aerogels are showing accelerated growth rates due to enhanced flexibility and processability, making them increasingly attractive for transportation, apparel, and aerospace applications. Carbon aerogels and bio-based variants are emerging as important segments for specialized applications in energy storage, catalysis, and sustainable materials.

Regionally, North America currently leads in revenue generation, though China is rapidly expanding manufacturing capacity. The European market remains strong, driven by stringent building insulation regulations and sustainability initiatives. The fastest-growing application sector is electric vehicle battery thermal management, expanding at over 40% annually as manufacturers adopt aerogel solutions for thermal runaway prevention and fire protection. The competitive landscape has evolved significantly, with established players expanding capacity while Chinese manufacturers such as Guangdong Alison and IBIH Advanced Materials rapidly scale up production. Smaller specialized producers have emerged focusing on niche applications and advanced formulations.

Technology advancements have been pivotal, with ambient pressure drying techniques reducing production costs compared to traditional supercritical methods. Manufacturing innovations including continuous roll-to-roll processes have improved scalability, while new hybrid formulations and composite structures have expanded performance capabilities. While high production costs and processing challenges persist for certain applications, these barriers are progressively diminishing as manufacturing scale increases. Market drivers including global energy efficiency regulations, building codes, EV safety standards, and industrial decarbonization initiatives continue to strengthen the value proposition for aerogel adoption across multiple sectors.

Looking forward, the aerogel market is positioned for continued strong growth as production costs decrease further and new applications emerge, particularly in transportation, sustainable building materials, energy storage, and high-performance industrial applications. The trend toward lightweight, high-efficiency materials across industries provides a strong foundation for aerogels' expanding market presence.

"The Global Aerogels Market 2025-2035" provides an in-depth analysis of the rapidly expanding global aerogels industry, with detailed segmentation by aerogel type, application sector, and geographic region. The executive summary covers aerogel properties, market position, drivers, production capacities, and technology challenges. The introduction section presents aerogel classification, commercially available types, and analysis of silica, polymer, metal oxide, organic, carbon, and hybrid aerogel variants. Production methodology content includes manufacturing processes from sol-gel synthesis through aging, surface modification, and drying techniques with cost assessments and manufacturing process evaluations.

Application sector analysis covers fifteen markets with drivers, aerogel types, performance advantages, technology readiness levels, and growth projections for building insulation, oil and gas, EV batteries, energy storage, biomedical applications, and textiles. Regional analysis examines China's expanding production capacity compared to North America and Europe's focus on high-value applications. The competitive landscape section contains profiles of 45 aerogel manufacturers.

The report features 40 tables and 45 figures showing market trends, material properties, manufacturing processes, and performance metrics, plus patent analysis tracking innovation activity. The forecasts through 2035 segment the market by aerogel type, application sectors, and geographical regions for precise market sizing and opportunity identification in this advanced materials sector.

Report Contents include:

  • Aerogel properties
  • Applications overview
  • Competitive landscape
  • Market drivers and trends
  • Production capacities
  • Technology challenges
  • Market forecasts 2021-2035
  • Types of Aerogels
    • Silica aerogels
    • Polymer-based aerogels
    • Metal oxide aerogels
    • Organic and biobased aerogels
    • Carbon aerogels
    • 3D printed aerogels
    • Hybrid and composite aerogels
  • Production Methods
  • Markets and Applications
    • Oil and gas
    • Building and construction
    • Energy storage
    • Biomedical
    • Cold-chain packaging
    • Electronics and telecommunications
    • Filtration and separation
    • Textiles
    • Food
    • Catalysts
    • Paint and coatings
    • Aerospace and defense
    • Cosmetics
    • Automotive and EV batteries
    • Other applications
  • Patent Analysis
    • Innovation trends
    • Key patent holders
  • Company Profiles (50 manufacturers)
    • Established market leaders
    • Emerging specialists
    • Regional manufacturers. Companies profiled include: ABIS Aerogel Co., Active Aerogels, Aerofybers Technologies SL, Aerogel Core Ltd, Aerogel Coating Technologies, aerogel-it GmbH, Aerogel Technologies LLC, AeroShield Materials, Armacell International S.A., Aspen Aerogels Inc., BASF SE, Blueshift Materials Inc., Cabot Corporation, Cellutech AB (Stora Enso), Dragonfly Insulation, Elisto GmbH, Enersens SAS, Fibenol, Fuji Silysia Chemical Ltd., Gelanggang Kencana Sdn. Bhd., Green Earth Aerogel Technologies, Guangdong Alison Hi-Tech Co. Ltd., Hebei Jinna Technology Co. Ltd., Hokuetsu Toyo Fibre Co. Ltd., IBIH Advanced Materials, Keey Aerogel and more
  • Market Forecasts 2021-2035
    • By aerogel type
    • By application market
    • By geographic region

TABLE OF CONTENTS

1. EXECUTIVE SUMMARY

  • 1.1. Aerogel properties
  • 1.2. Aerogel applications
  • 1.3. Competitive factors in the aerogels market
  • 1.4. Market drivers and trends
  • 1.5. Aerogel producers and capacities
  • 1.6. Market and technology challenges
  • 1.7. Market size and forecast 2021-2035
    • 1.7.1. By aerogel type
    • 1.7.2. By market
    • 1.7.3. By region

2. INTRODUCTION

  • 2.1. Aerogels
    • 2.1.1. Origin of Aerogels
    • 2.1.2. Classification
    • 2.1.3. Aerogel Forms
    • 2.1.4. Commercially available aerogels
  • 2.2. Silica aerogels
    • 2.2.1. Properties
      • 2.2.1.1. Thermal conductivity
      • 2.2.1.2. Mechanical
      • 2.2.1.3. Silica aerogel precursors
    • 2.2.2. Products
      • 2.2.2.1. Monoliths
      • 2.2.2.2. Powder
      • 2.2.2.3. Granules
      • 2.2.2.4. Blankets
      • 2.2.2.5. Aerogel boards
      • 2.2.2.6. Aerogel renders
      • 2.2.2.7. Silica aerogel from sustainable feedstocks
      • 2.2.2.8. Silica composite aerogels
        • 2.2.2.8.1. Organic crosslinkers
        • 2.2.2.8.2. Commercial activity
    • 2.2.3. Cost
    • 2.2.4. Main players
  • 2.3. Aerogel-like polymer foams
    • 2.3.1. Properties
    • 2.3.2. Applications for aerogel-like polymer foams include:
  • 2.4. Metal oxide aerogels
  • 2.5. Organic aerogels
    • 2.5.1. Polymer-based aerogels
    • 2.5.2. Biobased aerogels (bio-aerogels)
      • 2.5.2.1. Overview
      • 2.5.2.2. Sustainable Feedstocks
        • 2.5.2.2.1. Silica aerogels derived from waste sources
        • 2.5.2.2.2. Commercial development
        • 2.5.2.2.3. Textile waste into high-value aerogel materials
      • 2.5.2.3. Cellulose aerogels
        • 2.5.2.3.1. Cellulose nanofiber (CNF) aerogels
        • 2.5.2.3.2. Cellulose nanocrystal aerogels
        • 2.5.2.3.3. Bacterial nanocellulose aerogels
        • 2.5.2.3.4. Lignin aerogels
        • 2.5.2.3.5. Alginate aerogels
        • 2.5.2.3.6. Starch aerogels
        • 2.5.2.3.7. Chitosan aerogels
        • 2.5.2.3.8. Protein aerogels
          • 2.5.2.3.8.1. Albumin aerogels
          • 2.5.2.3.8.2. Casein aerogels
          • 2.5.2.3.8.3. Gelatin aerogels
        • 2.5.2.3.9. Silk fiber
    • 2.5.3. Carbon aerogels
      • 2.5.3.1. Carbon nanotube aerogels
      • 2.5.3.2. Graphene and graphite aerogels
  • 2.6. 3D printed aerogels
    • 2.6.1. Carbon nitride
      • 2.6.1.1. Gold
      • 2.6.1.2. Cellulose
      • 2.6.1.3. Graphene oxide
  • 2.7. Hybrid and composite aerogels
    • 2.7.1. Mixed oxide aerogels
    • 2.7.2. Metal oxide aerogel composites
    • 2.7.3. Carbon-based aerogel composites

3. PRODUCTION METHODS

  • 3.1. Overview
  • 3.2. Sol-gel process
  • 3.3. 3D printing of aerogels
  • 3.4. Drying methods
    • 3.4.1. Overview of drying methods
    • 3.4.2. Supercritical Drying
      • 3.4.2.1. Closed loop
      • 3.4.2.2. Autoclave loading
    • 3.4.3. Ambient Pressure Drying
    • 3.4.4. Rapid Supercritical Extraction (RSCE)
    • 3.4.5. Advantages and disadvantages
  • 3.5. Costs

4. MARKETS AND APPLICATIONS FOR AEROGELS

  • 4.1. Competitive landscape
  • 4.2. Oil and Gas
    • 4.2.1. Overview
    • 4.2.2. Applications
      • 4.2.2.1. Refineries
      • 4.2.2.2. Pipelines
  • 4.3. Building and Construction
    • 4.3.1. Overview
    • 4.3.2. Types of sustainable insulation materials
    • 4.3.3. Applications
      • 4.3.3.1. Panels and blankets
      • 4.3.3.2. Plaster, concrete and bricks
      • 4.3.3.3. Coatings and paints
      • 4.3.3.4. Windows/Daylighting
      • 4.3.3.5. Industrial insulation
  • 4.4. Energy Storage
    • 4.4.1. Overview
    • 4.4.2. Applications
      • 4.4.2.1. Silicon anodes
      • 4.4.2.2. Li-S batteries
      • 4.4.2.3. Electrodes
      • 4.4.2.4. Thermal insulation
      • 4.4.2.5. Supercapacitors
  • 4.5. Biomedical
    • 4.5.1. Overview
    • 4.5.2. Applications
      • 4.5.2.1. Drug delivery
      • 4.5.2.2. Tissue engineering
      • 4.5.2.3. Medical implants
      • 4.5.2.4. Wound care
  • 4.6. Cold-Chain Packaging
    • 4.6.1. Overview
  • 4.7. Electronics and Telecommunications
    • 4.7.1. Overview
    • 4.7.2. Applications
      • 4.7.2.1. EMI Shielding
      • 4.7.2.2. Thermal insulation
      • 4.7.2.3. 5G
        • 4.7.2.3.1. Antenna modules
        • 4.7.2.3.2. High-performance antenna substrates
        • 4.7.2.3.3. Advanced low-loss materials
  • 4.8. Filtration, Separation, and Sorption
    • 4.8.1. Overview
    • 4.8.2. Applications
      • 4.8.2.1. Sorbents for liquids, hazardous ions (heavy metal ions) (e.g., water treatment)
      • 4.8.2.2. Sorbent for oil spills
      • 4.8.2.3. Sorbents for gases (CO2, hazardous gases, VOC)
  • 4.9. Textiles
    • 4.9.1. Overview
    • 4.9.2. Applications
      • 4.9.2.1. Winter sports apparel
      • 4.9.2.2. Consumer apparel
      • 4.9.2.3. Protective equipment
      • 4.9.2.4. Footwear applications
  • 4.10. Food
    • 4.10.1. Overview
  • 4.11. Catalysts
  • 4.12. Paint and Coatings
  • 4.13. Aerospace and Defence
    • 4.13.1. Overview
    • 4.13.2. Applications
  • 4.14. Cosmetics
    • 4.14.1. Overview
  • 4.15. Automotive
    • 4.15.1. Overview
    • 4.15.2. EV batteries
      • 4.15.2.1. Fire protection
      • 4.15.2.2. Thermal barriers
      • 4.15.2.3. Regulations
      • 4.15.2.4. Challenges
      • 4.15.2.5. Integration of aerogels with specialized foam materials
      • 4.15.2.6. Companies
  • 4.16. Other markets and applications

5. AEROGEL PATENTS

  • 5.1. Patent applications

6. AEROGEL COMPANY PROFILES (50 company profiles)

7. RESEARCH SCOPE AND METHODOLOGY

  • 7.1. Report scope
  • 7.2. Research methodology

8. REFERENCES

Tables

  • Table 1. General properties and value of aerogels
  • Table 2. Aerogel Thermal Conductivity and Density Benchmarking
  • Table 3. Market drivers for aerogels
  • Table 4. Aerogel Manufacturer Production Capacity and Manufacturing Processes
  • Table 5. Planned aerogel production expansions
  • Table 6. Market and technology challenges in aerogels
  • Table 7. Aerogel Forecast 2021-2035 (Million USD), by aerogel type
  • Table 8. Aerogel Forecast 2021-2035 by Markets (Million USD)
  • Table 9. Aerogel Manufacturers in China
  • Table 10. Aerogel Forecast 2021-2035 by Region (Million USD)
  • Table 11. Aerogel Form Factors
  • Table 12. Commercially Available Aerogel Products
  • Table 13. Silica aerogel properties
  • Table 14. Chemical precursors used to synthesize silica aerogels
  • Table 15. Commercially available aerogel-enhanced blankets
  • Table 16. Commercial Silica Composite Aerogels
  • Table 17. Main manufacturers of silica aerogels and product offerings
  • Table 18. Typical structural properties of metal oxide aerogels
  • Table 19. Polymer aerogels companies
  • Table 20. Types of biobased aerogels
  • Table 21. Carbon aerogel companies
  • Table 22. Synthesis methods-Aerogels synthesised, advantages and disadvantages
  • Table 23. Silica Aerogel Powder Manufacturing Processes Using Ambient Drying
  • Table 24. Drying methods for aerogel production
  • Table 25. Advantages and disadvantages of drying methods
  • Table 26. Silica Composite Aerogels - Cost Analysis
  • Table 27. Cost Analysis by Aerogel Type
  • Table 28. Market overview of aerogels in oil and gas-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 29. Aerogel Products for Cryogenic Insulation
  • Table 30. Market overview of aerogels in building and construction-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 31. Aerogel Materials for Building & Construction Applications
  • Table 32. Aerogel Products for Windows/Daylighting
  • Table 33. Market overview of aerogels in energy conversion and storage-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 34. Market overview of aerogels in drug delivery-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 35. Market overview of aerogels in tissue engineering-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 36. Market overview of aerogels in medical implants-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 37. Market overview of aerogels in wound care-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 38. Market overview of aerogels in cold-chain packaging-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 39. Market overview of aerogels in electronics and Telecommunications-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 40. Aerogel Products for Electronic Appliances
  • Table 41. Market overview of aerogels in filtration, separation, and sorption-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 42. Market overview of aerogels in textiles- market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 43. Market overview of aerogels in food- market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 44. Market overview of aerogels in catalysts-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 45. Market overview of aerogels in paints and coatings-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 46. Market overview of aerogels in aerospace-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 47. Market overview of aerogels in cosmetics-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 48. Market overview of aerogels in automotive-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 49. Properties of Aerogels and Other Fire Protection Materials
  • Table 50. Types of Fire Protection Materials
  • Table 51. Thermally Insulating Fire Protection Products for EVs
  • Table 52. Comparison of Aerogels vs Other Fire Protection Materials
  • Table 53. Comparison of Aerogel Fire Protection Materials for EV Batteries
  • Table 54. Companies producing Aerogels for EV Batteries
  • Table 55. Other markets and applications for aerogels
  • Table 56. Aerogel patents 2010-2024

Figures

  • Figure 1. Classification of aerogels
  • Figure 2. SLENTEX-R thermal insulation
  • Figure 3. Aerogel Forecast 2021-2035 (Million USD), by aerogel type
  • Figure 4. Aerogel Forecast 2021-2035 by Markets (Million USD)
  • Figure 5. Aerogel Forecast 2021-2035 by Region (Million USD)
  • Figure 6. Main characteristics of aerogel type materials
  • Figure 7. Classification of aerogels
  • Figure 8. Canada Goose luxury footwear
  • Figure 9. Flower resting on a piece of silica aerogel suspended in mid air by the flame of a bunsen burner
  • Figure 10. Monolithic aerogel
  • Figure 11. Aerogel granules
  • Figure 12. Internal aerogel granule applications
  • Figure 13. Slentite
  • Figure 14. Methods for producing bio-based aerogels
  • Figure 15. Types of cellulose aerogel
  • Figure 16. Lignin-based aerogels
  • Figure 17. Fabrication routes for starch-based aerogels
  • Figure 18. Schematic of silk fiber aerogel synthesis
  • Figure 19. Graphene aerogel
  • Figure 20. Commonly employed printing technologies for aerogels
  • Figure 21. Schematic for direct ink writing of silica aerogels
  • Figure 22. 3D printed aerogel
  • Figure 23. Schematic of silica aerogels synthesis
  • Figure 24. Formation of aerogels, cryogels and xerogels
  • Figure 25. Aerogel engineering strategies
  • Figure 26. 3D printed aerogels
  • Figure 27. SEM images of the microstructures of (a) alginate and (b) pectin aerogels obtained by supercritical drying, (c) cellulose aerogels by freeze-drying, and (d) silica-cellulose composite aerogels by ambient drying
  • Figure 28. Methods of gel drying
  • Figure 29. Pyrogel insulation on a heat-exchange vessel in a petrochemical plant
  • Figure 30. Aerogel construction applications
  • Figure 31. Incorporation of aerogels into textiles
  • Figure 32. Aerogel dust collector
  • Figure 33. Thermal Conductivity Performance of ArmaGel HT
  • Figure 34. A pencil resting on a PyroThin thermal barrier to show its comparative thickness
  • Figure 35. SLENTEX-R roll (piece)
  • Figure 36. CNF gel
  • Figure 37. Block nanocellulose material
  • Figure 38. Keey Aerogel
  • Figure 39. Fire-resistance in Keey Aerogel
  • Figure 40. Melodea CNC suspension
  • Figure 41. HIP AERO paint
  • Figure 42. Insulation of various aerogel fibres illustrated using the example of a cushion,
  • Figure 43. Sunthru Aerogel pane
  • Figure 44. Quartzene-R