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市場調查報告書

世界氣凝膠市場(至2031年)

The Global Market for Aerogels to 2031

出版商 Future Markets, Inc. 商品編碼 997241
出版日期 內容資訊 英文 135 Pages, 37 Tables, 35 Figures
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世界氣凝膠市場(至2031年) The Global Market for Aerogels to 2031
出版日期: 2021年03月29日內容資訊: 英文 135 Pages, 37 Tables, 35 Figures
簡介

本報告分析了全球氣凝膠市場,包括產品特性和製造方法,主要市場推動者和抑制者,冠狀病毒感染(COVID-19)危機的影響以及總體市場規模。趨勢展望(2018-2031年),按類型/市場(按用途)/地區的詳細趨勢,最終用戶市場分析,相關專利的申請/獲取狀態,主要公司的概況等。我將其發送給您。

目錄

第1章執行摘要

  • 市場驅動力
  • 氣凝膠製造商和生產能力
  • 冠狀病毒感染(COVID-19)危機的影響
  • 市場/技術問題
  • 市場趨勢(2020-2021)

第2章氣凝膠的類型

  • 氣凝膠
    • 氣凝膠的開發過程
    • 分類方法
    • 市售氣凝膠
  • 氣凝膠的製造方法
    • 溶膠凝膠法
    • 老化
    • 疏水化/表面改性
    • 乾燥方式
  • 技術準備水平(TRL)
  • 氣凝膠市場中的競爭因素
  • 矽膠氣凝膠
    • 特徵
    • 產品
    • 主要公司
  • 氣凝膠狀聚合物泡沫
  • 金屬氧化物氣凝膠
  • 有機氣凝膠
    • 聚合物氣凝膠
    • 生物基氣凝膠(bio airgel)
    • 碳氣凝膠
    • 碳納米管氣凝膠
    • 石墨烯氣凝膠
    • 3D打印氣凝膠
  • 混合/複合氣凝膠
    • 混合氧化物氣凝膠
    • 金屬氧化物氣凝膠複合材料
    • 碳基氣凝膠複合材料

第3章氣凝膠市場和應用

  • 競爭形勢
  • 石油和天然氣
    • 市場概況
  • 建築業
  • 能量轉換/存儲
  • 生物醫學
    • 藥物輸送
    • 人體組織工程
    • 醫用植入物
    • 傷口處理
  • 冷鏈包裝
  • 電子
  • 過濾/分離/收集
  • 高性能紡織品
  • 食物
  • 催化劑
  • 油漆和塗料添加劑
  • 航空航天
  • 化妝品
  • 其他市場和用途

第4章氣凝膠專利

  • 專利申請趨勢

第5章,全球氣凝膠市場的收入趨勢

  • 總計(2018-2031)
  • 按市場劃分(2018-2031)
  • 按材料分類(2018-2031)
  • 按地區(2018-2031)

第6章(所有37家公司)的氣凝膠公司簡介

第7章在氣凝膠市場上經營的其他公司

第8章和更早的製造商

第9章分析範圍/方法

第10章參考

目錄

Aerogels demonstrate exceptional performance as thermal, acoustic absorbents or insulators, shock absorbers, in batteries, as electrical insulators, as catalyst supports, drug carriers, cosmic dust collectors, and in nuclear-waste storage materials. Aerogels are the most promising, high-performance thermal and acoustic insulation materials for building applications; and their high visible, solar radiation transmittance is a desirable attribute for application in insulating windows.

Aerogels are highly porous nanostructured materials that exhibit special characteristics including:

  • low density;
  • low thermal conductivity;
  • high surface area (150 m2/g and above);
  • high and open porosity (typically in the 95-99.99 % range);
  • excellent impact damping properties;
  • flame and moisture resistance;
  • low optical index of refraction;
  • high air flowability;
  • low speed of sound;
  • high loading capacity;
  • tuneable chemical functionalities;
  • renewable resources;
  • low dielectric constant.

These properties are desirable for applications in:

  • Biomedical
  • Drug delivery carriers.
  • Tissue engineering (synthetic bone grafts).
  • Wound dressings.
  • Energy infrastructure
  • Refineries.
  • Petrochemical.
  • Oil sands.
  • Offshore.
  • Power generation.
  • Environmental absorbents, sensors and catalysts
  • Wastewater treatment.
  • Air and water pollutant detection.
  • Sound insulation.
  • Food
  • Delivery.
  • Food additives.
  • Storage of temperature-sensitive food.
  • Building and construction
  • Non-combustible thermal insulation.
  • Composite panels and blankets.
  • Insulated spray rendering.
  • Polycarbonate wall panels.
  • Coatings and paints
  • Window insulation.
  • Removal of indoor air contaminants.
  • Energy conversion and storage
  • Lithium-ion batteries.
  • Electric vehicles.
  • Supercapacitors.
  • Fuel cells.
  • Solar.
  • Apparel and textiles.
  • Thermal insulation.
  • Antibacterial textiles.
  • Medical textiles.
  • Flame retardant textiles.
  • Footwear.
  • Cold-chain packaging.
  • Insulated packaging.
  • Aerospace.
  • Cosmetics.
  • Sport goods composites.

Aerogels can be divided into two broad categories, namely inorganic and organic, each category being further divided according to the nature of the materials used in the design of the gel structure.

Report contents include:

  • Market drivers.
  • Market challenges.
  • Recent market activity.
  • Impact of COVID-19 crisis on the aerogels market.
  • Assessment of aerogels market by types.
  • Global revenues 2018 to 2031 by type, markets and regions.
  • End user market analysis.
  • Patent analysis.
  • Assessment of key industry players.
  • 37 Company profiles. Companies profiled include Armacell, Aspen Aerogel, Blueshift Materials, Cabot Corporation, Enersens SAS, JIOS Aerogel, Guangdong Alison Hi-Tech Co., Ltd. and many more.

TABLE OF CONTENTS

1. EXECUTIVE SUMMARY

  • 1.1. Market drivers
  • 1.2. Aerogel producers and capacities
  • 1.3. Impact of COVID-19 crisis
  • 1.4. Market and technology challenges
  • 1.5. Market developments 2020-2021

2. TYPES OF AEROGELS

  • 2.1. Aerogels
    • 2.1.1. Origin of Aerogels
    • 2.1.2. Classification
    • 2.1.3. Commercially available aerogels
  • 2.2. Production methods for aerogels
    • 2.2.1. Sol-gel process
    • 2.2.2. Aging
    • 2.2.3. Hydrophobization/surface modification
    • 2.2.4. Drying methods
      • 2.2.4.1. Overview of drying methods
      • 2.2.4.2. Advantages and disadvantages
  • 2.3. Technology Readiness Level (TRL)
  • 2.4. Competitive factors in the aerogels market
  • 2.5. Silica aerogels
    • 2.5.1. Properties
      • 2.5.1.1. Thermal conductivity
      • 2.5.1.2. Mechanical
    • 2.5.2. Products
      • 2.5.2.1. Monoliths
      • 2.5.2.2. Powder
      • 2.5.2.3. Granules
      • 2.5.2.4. Blankets
      • 2.5.2.5. Aerogel boards
      • 2.5.2.6. Aerogel renders
      • 2.5.2.7. Cost
    • 2.5.3. Main players
  • 2.6. Aerogel-like polymer foams
  • 2.7. Metal oxide aerogels
  • 2.8. Organic aerogels
    • 2.8.1. Polymer aerogels
      • 2.8.1.1. Companies
    • 2.8.2. Biobased aerogels (bio-aerogels)
      • 2.8.2.1. Cellulose aerogels
      • 2.8.2.2. Lignin aerogels
      • 2.8.2.3. Alginate aerogels
      • 2.8.2.4. Starch aerogels
      • 2.8.2.5. Chitosan aerogels
      • 2.8.2.6. Protein aerogels
      • 2.8.2.7. Silk fiber
    • 2.8.3. Carbon aerogels
      • 2.8.3.1. Companies
    • 2.8.4. Carbon nanotube aerogels
    • 2.8.5. Graphene aerogels
    • 2.8.6. 3D printed aerogels
  • 2.9. Hybrid and composite aerogels
    • 2.9.1. Mixed oxide aerogels
    • 2.9.2. Metal oxide aerogel composites
    • 2.9.3. Carbon-based aerogel composites

3. MARKETS AND APPLICATIONS FOR AEROGELS

  • 3.1. Competitive landscape
  • 3.2. Oil and Gas
    • 3.2.1. Market overview
  • 3.3. Building and construction
    • 3.3.1. Market overview
  • 3.4. Energy conversion and storage
    • 3.4.1. Market overview
  • 3.5. Biomedical
    • 3.5.1. Drug delivery
      • 3.5.1.1. Market overview
    • 3.5.2. Tissue engineering
      • 3.5.2.1. Market overview
    • 3.5.3. Medical implants
      • 3.5.3.1. Market overview
    • 3.5.4. Wound care
      • 3.5.4.1. Market overview
  • 3.6. Cold-Chain packaging
    • 3.6.1. Market overview
  • 3.7. Electronics
    • 3.7.1. Market overview
  • 3.8. Filtration, separation, and sorption
    • 3.8.1. Market overview
  • 3.9. High-performance textiles
    • 3.9.1. Market overview
  • 3.10. Food
    • 3.10.1. Market overview
  • 3.11. Catalysts
    • 3.11.1. Market overview
  • 3.12. Paint and coating additives
    • 3.12.1. Market overview
  • 3.13. Aerospace
    • 3.13.1. Market overview
  • 3.14. Cosmetics
    • 3.14.1. Market overview
  • 3.15. Automotive
    • 3.15.1. Market overview
  • 3.16. Other markets and applications

4. AEROGEL PATENTS

  • 4.1. Patent applications

5. GLOBAL AEROGELS REVENUES

  • 5.1. Total, 2018-2031
  • 5.2. By market, 2018-2031
  • 5.3. By material, 2018-2031
  • 5.4. By region, 2018-2031

6. AEROGEL COMPANY PROFILES. 83 (37 COMPANY PROFILES)

7. OTHER COMPANIES WITH AEROGEL ACTIVITIES

8. EX-PRODUCERS

9. RESEARCH SCOPE AND METHODOLOGY

  • 9.1. Report scope
  • 9.2. Research methodology

10. REFERENCES

Tables

  • Table 1. Market drivers for aerogels
  • Table 2. Aerogel producers and capacities-current and planned
  • Table 3. Assessment of impact from COVID-19 crisis by end user market. Key: Low, little impact and market will continue to grow. Medium, market impacted to some degree affecting growth prospects over next 1-2 years. High: Market significantly impacted
  • Table 4. Market and technology challenges in aerogels
  • Table 5. Aerogels market developments 2020-2021
  • Table 6. General properties and value of aerogels
  • Table 7. Synthesis methods-Aerogels synthesised, advantages and disadvantages
  • Table 8. Drying methods for aerogel production
  • Table 9. Advantages and disadvantages of drying methods
  • Table 10. Technology Readiness Level (TRL) Examples
  • Table 11. Commercially available aerogel-enhanced blankets
  • Table 12. Main manufacturers of silica aerogels and product offerings
  • Table 13. Typical structural properties of metal oxide aerogels
  • Table 14. Polymer aerogels companies
  • Table 15. Types of biobased aerogels
  • Table 16. Carbon aerogel companies
  • Table 17. Market overview of aerogels in oil and gas-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 18. Market overview of aerogels in building and construction-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 19. Market overview of aerogels in energy conversion and storage-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 20. Market overview of aerogels in drug delivery-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 21. Market overview of aerogels in tissue engineering-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 22. Market overview of aerogels in medical implants-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 23. Market overview of aerogels in wound care-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 24. Market overview of aerogels in cold-chain packaging-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 25. Market overview of aerogels in electronics-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 26. Market overview of aerogels in filtration, separation, and sorption-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 27. Market overview of aerogels in textiles- market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 28. Market overview of aerogels in food- market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 29. Market overview of aerogels in catalysts-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 30. Market overview of aerogels in paints and coatings-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 31. Market overview of aerogels in aerospace-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 32. Market overview of aerogels in cosmetics-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 33. Market overview of aerogels in automtotive-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL
  • Table 34. Other markets and applications for aerogels
  • Table 35. Global market for aerogels, 2018-2031, millions USD
  • Table 36. Other companies with aerogel activities
  • Table 37. Aerogel producers no longer trading

Figures

  • Figure 1. SLENTEX® thermal insulation
  • Figure 2. Main characteristics of aerogel type materials
  • Figure 3. Classification of aerogels
  • Figure 4. Schematic of silica aerogels synthesis
  • Figure 5. Aerogel engineering strategies
  • Figure 6. 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 7. Methods of gel drying
  • Figure 8. Technology Readiness Level (TRL) for aerogels
  • 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. Fabrication routes for starch-based aerogels
  • Figure 16. Schematic of silk fiber aerogel synthesis
  • Figure 17. Commonly employed printing technologies for aerogels
  • Figure 18. Schematic for direct ink writing of silica aerogels
  • Figure 19. 3D printed aerogel
  • Figure 20. Segmentation of the aerogel market by application, 2020
  • Figure 21. Pyrogel insulation on a heat-exchange vessel in a petrochemical plant
  • Figure 22. Aerogel construction applications
  • Figure 23. Aerogel dust collector
  • Figure 24. Aerogel patents 2010-2021
  • Figure 25. Global market for aerogels, 2018-2031, millions USD
  • Figure 26. Global market for aerogels, 2018-2031, millions USD, by market
  • Figure 27. Global market for aerogels, 2018-2031, millions USD, by material
  • Figure 28. Global market for aerogels, 2018-2031, millions USD, by region
  • Figure 29. Lignin Aero gel plate
  • Figure 30. Thermal Conductivity Performance of ArmaGel HT
  • Figure 31. SLENTEX® roll (piece)
  • Figure 32. CNF gel
  • Figure 33. Block nanocellulose material
  • Figure 34. Melodea CNC suspension
  • Figure 35. Quartzene®