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The Global Market for Advanced Fibers 2022-2032

January 2022 | 782 pages | ID: G4FB90A9F055EN
Future Markets, Inc.

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Advanced fiber materials are increasingly used in:
  • composites (including automobile, aerospace industry, and sporting goods)
  • environmental (pollution control and purification for water, air and earth)
  • energy storage and generation (solar cells, lithium batteries, supercapacitor, etc.)
  • biomedical applications (regenerative medicine, drug delivery, tumor therapy, etc)
Their use will increase greatly in these and other markets in the next 10-15 years. Carbon fibers, polymer nanofibers, cellulose nanofibers and carbon fibers will play a significant role in technology advancement across these markers. The use of natural fibers for advanced technology applications will also play a major role in the development of renewable solutions in polymer composites, construction and building materials, packaging, and replacement for plastics in consumer products. Natural fibers possess advantages over synthetic fibres including widespread availability, low cost, low density, acceptable modulus-weight ratio, high acoustic damping, low manufacturing energy consumption, low carbon footprint and biodegradability.

The Global Market for Advanced Fibers 2022-2032 includes:
  • Global production capacities, by producers, current and planned.
  • Production volumes by region.
  • Commercialized products.
  • Market and technical developments in advanced fibers 2020-2022.
  • Advanced Fiber applications by industry.
  • Figures for current carbon fiber and CFRP demand, production capacities and projected future demand to 2031, by metric tonnes, end user markets and regions.
  • Assessment of developments in plant-based carbon fibers, low cost production, alternative precursors and processes, and 3D printing.
  • Demand in tons per market, current and forecast to 2032.
  • Market drivers, trends and challenges, by end user markets.
  • Competitive landscape of advanced fibers by market, volumes, key trends and growth. Potential for advanced fibers to gain market share by market volume across all end user markets. Markets covered include Polymer composites, Automotive, Building & Construction, Packaging, Textiles, Biomedicine, Pharma, Healthcare, Sanitary and Hygiene Products, Paints & Coatings, Aerogels, Oil & Gas, Filtration, Cosmetics, Food Additives, Electronics, Batteries, Aerospace and 3D printing etc.
  • In-depth profiles of 95 carbon fiber companies including CF manufacturers, CFRP manufacturers and CF recyclers. Companies profiled include DowAksa, Formosa Plastics Corporation, Hexcel Corporation, Hyosung Advanced Materials, Jiangsu Hengshen Co., Ltd., Kureha Corporation, Mitsubishi Chemical Corporation, SGL Carbon SE, Solvay SA, Teijin Limited, Toray Industries, Inc., UMATEX, bCircular, Carbon Conversions, Gen 2 Carbon, Mallinda, Carbitex, LeMond Carbon, Continuous Composites, Boston Materials and 9T Labs.
  • In-depth profiles of 65 polymer nanofiber companies, include products commercial activities. Nanofiber companies profiled include Bioinicia SL, Donaldson, 4C Air Inc, Gelatex Technologies, Lime Co., Ltd., Matregenix, M-TEchX, Vivolta and many more.
  • In-depth profiles of 10 carbon nanofiber companies, include products commercial activities. Nanofiber companies profiled include Bergen Carbon Solutions, Carbonova, Grupo Antolin etc.
  • In-depth profiles of 93 cellulose nanofiber companies, including products, current capacities and plans for new capacities, production processes, prices per kg and commercial activities. Companies profiled in the report include Asahi Kasei, Chuetsu Pulp & Paper Daicel, Daiichi Kogyo, Daio Paper, GranBio Technologies, Nippon Paper, Oji Holdings, Sugino Machine, Seiko PMC and more.
  • In-depth profiles of 143 natural fiber companies. Companies profiled include Ananas Anam, BASF, Bast Fiber Technologies Inc., Kelheim Fibres GmbH, BComp, Circular Systems, Evrnu, Natural Fiber Welding, Icytos and many more.
1 CARBON FIBER AND CARBON FIBER REINFORCED POLYMERS (CFRP) MARKET

1.1 Key players
1.2 Market drivers and trends
1.3 Market challenges
1.4 Future trends
1.5 Technology analysis
  1.5.1 Properties of carbon fibers
  1.5.2 Types by modulus
  1.5.3 Types by the secondary processing
  1.5.4 Precursor material types
    1.5.4.1 PAN: Polyacrylonitrile
    1.5.4.2 Pitch-based carbon fibers
    1.5.4.3 Viscose (Rayon)-based carbon fibers
  1.5.5 Carbon fiber reinforced polymer (CFRP)
    1.5.5.1 Applications
  1.5.6 Bio-based and alternative precursors
    1.5.6.1 Lignin
    1.5.6.2 Polyethylene
    1.5.6.3 Vapor grown carbon fiber (VGCF)
    1.5.6.4 Textile PAN
  1.5.7 Recycled carbon fibers (r-CF)
    1.5.7.1 Recycling processes
    1.5.7.2 Companies
  1.5.8 Carbon Fiber 3D Printing
  1.5.9 Plasma oxidation
1.6 Carbon fiber production capacities
  1.6.1 Annual capacity, by producer
  1.6.2 Market share, by capacity
1.7 Markets for carbon fibers
  1.7.1 Carbon fiber industry developments 2020-2022
  1.7.2 Aerospace
    1.7.2.1 Market drivers, applications, desirable properties, pricing and key players
    1.7.2.2 Global demand
  1.7.3 Wind energy
    1.7.3.1 Market drivers, applications, desirable properties, pricing and key players
    1.7.3.2 Offshore
    1.7.3.3 Global demand
  1.7.4 Sports & leisure
    1.7.4.1 Market drivers, applications, desirable properties, pricing and key players
    1.7.4.2 Global demand
  1.7.5 Automotive
    1.7.5.1 Market drivers, applications, desirable properties, pricing and key players
    1.7.5.2 Global demand
  1.7.6 Pressure vessels
    1.7.6.1 Market drivers, applications, desirable properties, pricing and key players
    1.7.6.2 Global demand
  1.7.7 Oil and gas
    1.7.7.1 Market drivers, applications, desirable properties, pricing and key players
  1.7.8 Other markets
    1.7.8.1 Construction & infrastructure
    1.7.8.2 Medical
1.8 Global demand
  1.8.1 Demand by market 2018-2032
    1.8.1.1 Carbon fiber
    1.8.1.2 Carbon fiber reinforced polymers (CFRP)
  1.8.2 Demand by region 2018-2032
1.9 Company profiles
  1.9.1 Carbon fiber producers
  1.9.2 Carbon Fiber composite producers
  1.9.3 Carbon fiber recyclers

2 NATURAL FIBERS

2.1 What are natural fibers?
2.2 Benefits of natural fibers over synthetic
2.3 Markets and applications for natural fibers
2.4 Market drivers for natural fibers
2.5 Challenges
2.6 Covid-19 impact
2.7 Natural fiber types
  2.7.1 Manufacturing method, matrix materials and applications of natural fibers
  2.7.2 Advantages of natural fibers
  2.7.3 Plants (cellulose, lignocellulose)
    2.7.3.1 Seed fibers
    2.7.3.2 Bast fibers
    2.7.3.3 Leaf fibers
    2.7.3.4 Fruit fibers
    2.7.3.5 Stalk fibers from agricultural residues
    2.7.3.6 Cane, grasses and reed
    2.7.3.7 Modified natural polymers
  2.7.4 Animal (fibrous protein)
    2.7.4.1 Wool
    2.7.4.2 Silk fiber
    2.7.4.3 Leather
    2.7.4.4 Down
2.8 Markets for natural fibers
  2.8.1 Composites
    2.8.1.1 Applications
    2.8.1.2 Natural fiber injection moulding compounds
    2.8.1.3 Non-woven natural fiber mat composites
    2.8.1.4 Aligned natural fiber-reinforced composites
    2.8.1.5 Natural fiber biobased polymer compounds
    2.8.1.6 Natural fiber biobased polymer non-woven mats
    2.8.1.7 Natural fiber thermoset bioresin composites
  2.8.2 Aerospace
    2.8.2.1 Market overview
  2.8.3 Automotive
    2.8.3.1 Market overview
    2.8.3.2 Applications of natural fibers
  2.8.4 Building/construction
    2.8.4.1 Market overview
    2.8.4.2 Applications of natural fibers
  2.8.5 Sports and leisure
    2.8.5.1 Market overview
  2.8.6 Textiles
    2.8.6.1 Market overview
    2.8.6.2 Consumer apparel
    2.8.6.3 Geotextiles
  2.8.7 Packaging
    2.8.7.1 Market overview
2.9 Global natural fibers market
  2.9.1 Overall global fibers market
  2.9.2 Plant-based fiber production
  2.9.3 Animal-based natural fiber production
2.10 Natural fiber producer and producer developer profiles

3 NANOFIBERS

3.1 Market landscape
3.2 Polymer, alumina and carbon nanofibers
3.3 Applications
3.4 Commercial electrospun nanofiber products
3.5 Market drivers
3.6 Market and technical challenges
3.7 Global nanofibers market revenues
  3.7.1 Global revenues for nanofibers, by market 2018-2032
  3.7.2 Global revenues for nanofibers, by regions 2018-2032
3.8 Technology analysis
  3.8.1 Types of nanofibers
  3.8.2 Classification of nanofibers
  3.8.3 Synthetic polymer nanofibers
  3.8.4 Natural polymers
    3.8.4.1 Collagen
    3.8.4.2 Cellulose
    3.8.4.3 Silk fibroins
    3.8.4.4 Keratin
    3.8.4.5 Gelatin
    3.8.4.6 Polysaccharides
  3.8.5 Carbon nanofibers
  3.8.6 Other types of nanofibers
    3.8.6.1 Alumina nanofibers
    3.8.6.2 Silicon nanofibers
3.9 Upscaling nanofibers
3.10 Synthesis of nanofibers
  3.10.1 Electrospinning
    3.10.1.1 Advantages
    3.10.1.2 Drawbacks
    3.10.1.3 Multi-nozzle/needle electrospinning
    3.10.1.4 Needle/nozzle-less electrospinning
    3.10.1.5 Co-electrospinning or co-axial electrospinning
    3.10.1.6 Ultrasound-enhanced electrospinning
    3.10.1.7 Electrospinning instrument manufacturers
  3.10.2 Electro-hydrodynamic direct writing
  3.10.3 Electrospray Deposition
  3.10.4 Centrifugal jet spinning
  3.10.5 Centrifugal multi-spinning
  3.10.6 Plasma-induced synthesis
  3.10.7 CO2 laser supersonic drawing
  3.10.8 Solution blow spinning
3.11 Nanofibers Technology Readiness Levels (TRL)
3.12 Markets for polymer nanofibers
  3.12.1 Markets and application summary
  3.12.2 Filter media
    3.12.2.1 Market drivers
    3.12.2.2 Applications
    3.12.2.3 Global market revenues
    3.12.2.4 Market challenges
  3.12.3 Textiles
    3.12.3.1 Market drivers
    3.12.3.2 Applications
    3.12.3.3 Global market revenues
    3.12.3.4 Market challenges
  3.12.4 Medical and healthcare
    3.12.4.1 Market drivers
    3.12.4.2 Applications
    3.12.4.3 Products
    3.12.4.4 Global market revenues
  3.12.5 Other markets
3.13 Polymer nanofibers

4 CARBON NANOFIBERS

4.1 Properties
4.2 Synthesis
  4.2.1 Chemical vapor deposition
  4.2.2 Electrospinning
  4.2.3 Template-based
  4.2.4 From biomass
4.3 Markets
  4.3.1 Batteries
  4.3.2 Supercapacitors
  4.3.3 Fuel cells
  4.3.4 CO2 capture
4.4 Companies

5 CELLULLOSE NANOFIBERS

5.1 Cellulose
5.2 Nanocellulose
5.3 Properties of nanocellulose
5.4 Advantages of nanocellulose
5.5 Manufacture of nanocellulose
5.6 Production methods
5.7 Types of nanocellulose
  5.7.1 Microfibrillated cellulose (MFC)
  5.7.2 Cellulose nanofibers (CNF)
    5.7.2.1 Applications
  5.7.3 Cellulose nanocrystals (CNC)
    5.7.3.1 Synthesis
    5.7.3.2 Properties
    5.7.3.3 Applications
  5.7.4 Bacterial Nanocellulose (BNC)
    5.7.4.1 Applications
  5.7.5 Synthesis
5.8 Cellulose nanofibers pricing
5.9 Markets for cellulose nanofibers
  5.9.1 Composites
    5.9.1.1 Market overview
    5.9.1.2 Applications
    5.9.1.3 Global market in tons to 2032
    5.9.1.4 Product developers
  5.9.2 Automotive
    5.9.2.1 Market overview
    5.9.2.2 Applications
    5.9.2.3 Global market in tons to 2032
    5.9.2.4 Product developers
  5.9.3 Buildings and construction
    5.9.3.1 Market overview
    5.9.3.2 Applications
    5.9.3.3 Global market in tons to 2032
    5.9.3.4 Product developers
  5.9.4 Paper and board packaging
    5.9.4.1 Market overview
    5.9.4.2 Applications
    5.9.4.3 Global market in tons to 2032
    5.9.4.4 Product developers
  5.9.5 Textiles and apparel
    5.9.5.1 Market overview
    5.9.5.2 Applications
    5.9.5.3 Global market in tons to 2032
    5.9.5.4 Product developer profiles
  5.9.6 Biomedicine and healthcare
    5.9.6.1 Market overview
    5.9.6.2 Applications
    5.9.6.3 Global market in tons to 2032
    5.9.6.4 Product developers
  5.9.7 Hygiene and sanitary products
    5.9.7.1 Market overview
    5.9.7.2 Applications
    5.9.7.3 Global market in tons to 2032
    5.9.7.4 Product developers
  5.9.8 Paints and coatings
    5.9.8.1 Market overview
    5.9.8.2 Applications
    5.9.8.3 Global market in tons to 2032
    5.9.8.4 Product developers
  5.9.9 Aerogels
    5.9.9.1 Market overview
    5.9.9.2 Global market in tons to 2032
    5.9.9.3 Product developers
  5.9.10 Oil and gas
    5.9.10.1 Market overview
    5.9.10.2 Applications
    5.9.10.3 Global market in tons to 2032
    5.9.10.4 Product developers
  5.9.11 Filtration
    5.9.11.1 Market overview
    5.9.11.2 Applications
    5.9.11.3 Global market in tons to 2032
    5.9.11.4 Product developers
  5.9.12 Rheology modifiers
    5.9.12.1 Market overview
    5.9.12.2 Applications
    5.9.12.3 Global market in tons to 2032
    5.9.12.4 Product developers
  5.9.13 Other markets
    5.9.13.1 Printed, stretchable and flexible electronics
    5.9.13.2 3D printing
    5.9.13.3 Aerospace
    5.9.13.4 Batteries
5.10 Cellulose nanofiber company profiles

6 REFERENCES

LIST OF TABLES

Table 1. Market drivers and trends in carbon fibers.
Table 2. Market challenges in the CF and CFRP market.
Table 3. Classification and types of the carbon fibers.
Table 4. Summary of carbon fiber properties.
Table 5. Modulus classifications of carbon fiber.
Table 6. Comparison of main precursor fibers.
Table 7. Summary of markets and applications for CFRPs.
Table 8. Properties of lignins and their applications.
Table 9. Fiber properties of polyolefin-based CFs.
Table 10. Summary of carbon fiber (CF) recycling technologies. Advantages and disadvantages.
Table 11. Retention rate of tensile properties of recovered carbon fibres by different recycling processes.
Table 12. Recycled carbon fiber producers, technology and capacity.
Table 13. Methods for direct fiber integration.
Table 14. Continuous fiber 3D printing producers.
Table 15. Production capacities of carbon fiber producers, in metric tonnes.
Table 16. Carbon fiber industry developments 2020-2022.
Table 17. Comparison of CFRP to competing materials.
Table 18. The market for carbon fibers in aerospace-market drivers, applications, desirable properties, pricing and key players.
Table 19. Global demand for carbon fibers 2016-2032, in aerospace (metric tonnes).
Table 20. Global revenues for CFRP 2016-2032, in aerospace (billions USD).
Table 21. The market for carbon fibers in wind energy-market drivers, applications, desirable properties, pricing and key players.
Table 22. Global demand for carbon fibers 2016-2032, in wind energy (metric tonnes).
Table 23. Global revenues for CFRP 2016-2032, in wind energy (billions USD).
Table 24. The market for carbon fibers in sports & leisure-market drivers, applications, desirable properties, pricing and key players.
Table 25. Global demand for carbon fibers 2016-2032, in sports & leisure (metric tonnes).
Table 26. Global revenues for CFRP 2016-2032, in sports & leisure (billions USD).
Table 27. The market for carbon fibers in automotive-market drivers, applications, desirable properties, pricing and key players.
Table 28. Global demand for carbon fibers 2016-2032, in automotive (metric tonnes).
Table 29. Global revenues for CFRP 2016-2032, in automotive (billions USD).
Table 30. The market for carbon fibers in pressure vessels-market drivers, desirable properties of CF, applications, pricing, key players.
Table 31. Global demand for carbon fibers 2016-2032, in pressure vessels (metric tonnes).
Table 32. Global revenues for CFRP 2016-2032, in pressure vessels (billions USD).
Table 33. The market for carbon fibers in oil and gas-market drivers, desirable properties, applications, pricing and key players.
Table 34. Global demand for carbon fibers 2016-2032, in oil and gas (metric tonnes).
Table 35. Global revenues for CFRP 2016-2032, in oil and gas (billions USD).
Table 36. The market for carbon fibers in construction & infrastructure.
Table 37. The market for carbon fibers in medical.
Table 38. Global demand for carbon fibers 2016-2032, by market (metric tonnes).
Table 39. Global market revenues for Carbon fiber reinforced polymers (CFRP) 2016-2032, by market (billion USD).
Table 40. Global demand for carbon fibers 2018-2032, by region (thousand metric tonnes).
Table 41. Main Toray production sites and capacities.
Table 42. Types of natural fibers.
Table 43. Markets and applications for natural fibers.
Table 44. Market drivers for natural fibers.
Table 45. Application, manufacturing method, and matrix materials of natural fibers.
Table 46. Typical properties of natural fibers.
Table 47. Overview of cotton fibers-description, properties, drawbacks and applications.
Table 48. Overview of kapok fibers-description, properties, drawbacks and applications.
Table 49. Overview of luffa fibers-description, properties, drawbacks and applications.
Table 50. Overview of jute fibers-description, properties, drawbacks and applications.
Table 51. Overview of hemp fibers-description, properties, drawbacks and applications.
Table 52. Overview of flax fibers-description, properties, drawbacks and applications.
Table 53. Overview of ramie fibers- description, properties, drawbacks and applications.
Table 54. Overview of kenaf fibers-description, properties, drawbacks and applications.
Table 55. Overview of sisal fibers-description, properties, drawbacks and applications.
Table 56. Overview of abaca fibers-description, properties, drawbacks and applications.
Table 57. Overview of coir fibers-description, properties, drawbacks and applications.
Table 58. Overview of banana fibers-description, properties, drawbacks and applications.
Table 59. Overview of pineapple fibers-description, properties, drawbacks and applications.
Table 60. Overview of rice fibers-description, properties, drawbacks and applications.
Table 61. Overview of corn fibers-description, properties, drawbacks and applications.
Table 62. Overview of switch grass fibers-description, properties and applications.
Table 63. Overview of sugarcane fibers-description, properties, drawbacks and application and market size.
Table 64. Overview of bamboo fibers-description, properties, drawbacks and applications.
Table 65. Overview of mycelium fibers-description, properties, drawbacks and applications.
Table 66. Overview of chitosan fibers-description, properties, drawbacks and applications.
Table 67. Overview of alginate-description, properties, application and market size.
Table 68. Overview of wool fibers-description, properties, drawbacks and applications.
Table 69. Alternative wool materials producers.
Table 70. Overview of silk fibers-description, properties, application and market size.
Table 71. Alternative silk materials producers.
Table 72. Alternative leather materials producers.
Table 73. Alternative down materials producers.
Table 74. Applications of natural fiber composites.
Table 75. Typical properties of short natural fiber-thermoplastic composites.
Table 76. Properties of non-woven natural fiber mat composites.
Table 77. Properties of aligned natural fiber composites.
Table 78. Properties of natural fiber-bio-based polymer compounds.
Table 79. Properties of natural fiber-bio-based polymer non-woven mats.
Table 80. Natural fibers in the aerospace sector-market drivers, applications and challenges for NF use.
Table 81. Natural fiber-reinforced polymer composite in the automotive market.
Table 82. Natural fibers in the aerospace sector- market drivers, applications and challenges for NF use.
Table 83. Applications of natural fibers in the automotive industry.
Table 84. Natural fibers in the building/construction sector- market drivers, applications and challenges for NF use.
Table 85. Applications of natural fibers in the building/construction sector.
Table 86. Natural fibers in the sports and leisure sector-market drivers, applications and challenges for NF use.
Table 87. Natural fibers in the textiles sector-market drivers, applications and challenges for NF use.
Table 88. Natural fibers in the packaging sector-market drivers, applications and challenges for NF use.
Table 89: Market summary for nanofibers.
Table 90: Applications of nanofibers.
Table 91. Commercial electrospun nanofiber products
Table 92: Market drivers for nanofibers.
Table 93: Market and technical challenges for nanofibers.
Table 94: Global revenues for nanofibers, by market 2018-2032, millions USD.
Table 95: Global revenues for nanofibers by region 2018-2032 (million USD).
Table 96: Nanofibers types, properties and applications.
Table 97. Synthesis of nanofibers from various materials, their fabrication techniques, advantages and applications.
Table 98. Natural and synthetic polymers and blends that can be electrospun.
Table 99. Electrospinning instrument manufacturers.
Table 100. Technology Readiness Level (TRL) Examples.
Table 101. Markets and applications for polymer nanofibers.
Table 102. Market drivers for nanofibers in filter media.
Table 103: Types of filtration.
Table 104: Global revenues for nanofibers in the filter media market, 2018-2032 (million USD).
Table 105. Market drivers for use of nanofibers in textiles.
Table 106: Global revenues for nanofibers in the textiles market, 2018-2032 (millions USD).
Table 107: Market drivers for nanofibers in medical and healthcare.
Table 108: Nanofiber applications timeline in the medical and healthcare markets.
Table 109. Electrospun nanofiber medical products.
Table 110: Global revenues for nanofibers in the medical and healthcare market, 2018-2032 (million USD).
Table 111. Other markets for nanofibers.
Table 112. Gelatex nanofiber sheet.
Table 113. Comparison of synthesis methods for carbon nanofibers.
Table 114. Properties and applications of nanocellulose.
Table 115. Properties of nanocellulose, by type.
Table 116. Properties of cellulose nanofibrils relative to metallic and polymeric materials.
Table 117. Types of nanocellulose.
Table 118. Types of nanocellulose.
Table 119. Applications of cellulose nanofibers (CNF).
Table 120. Synthesis methods for cellulose nanocrystals (CNC).
Table 121. CNC sources, size and yield.
Table 122. CNC properties.
Table 123. Mechanical properties of CNC and other reinforcement materials.
Table 124. Applications of nanocrystalline cellulose (NCC).
Table 125. Applications of bacterial nanocellulose (BNC).
Table 126. Product/price/application matrix of cellulose nanofiber producers.
Table 127. Market overview for nanocellulose in composites.
Table 128. Comparative properties of polymer composites reinforcing materials.
Table 129. Scorecard for cellulose nanofibers in composites.
Table 130. Market assessment for cellulose nanofibers in composites-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading, main global composites OEMs.
Table 131. Global market demand for cellulose nanofibers in composites, 2018-2032 (metric tonnes).
Table 132. Companies developing cellulose nanofibers composites.
Table 133. Market overview for cellulose nanofibers in automotive.
Table 134. Scorecard for cellulose nanofibers in automotive.
Table 135. Market assessment for cellulose nanofibers in automotive-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading, main global automotive OEMs.
Table 136. Components featured in the NCV.
Table 137. Global market demand for cellulose nanofibers in the automotive sector 2018-2032 (tons).
Table 138. Companies developing cellulose nanofibers products in the automotive industry.
Table 139. Market overview for cellulose nanofibers in construction.
Table 140. Scorecard for cellulose nanofibers in construction
Table 141. Market assessment for cellulose nanofibers in construction-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading, main global construction OEMs
Table 142: Market demand for cellulose nanofibers in construction, 2018-2032 (tons).
Table 143. Companies developing cellulose nanofibers in construction.
Table 144. Oxygen permeability of nanocellulose films compared to those made form commercially available petroleum-based materials and other polymers.
Table 145. Scorecard for cellulose nanofibers in paper and board packaging.
Table 146. Market assessment for cellulose nanofibers in paper and board packaging-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading, main global paper and board packaging OEMs.
Table 147. Global demand for cellulose nanofibers in paper & board packaging, 2018-2032 (tons).
Table 148. Companies developing cellulose nanofibers products in paper and board.
Table 149. Market overview for cellulose nanofibers in textiles and apparel.
Table 150. Scorecard for cellulose nanofibers in textiles and apparel.
Table 151. Market assessment for cellulose nanofibers in textiles and apparel-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading, main global textiles and apparel OEMs.
Table 152. Demand for cellulose nanofibers in textiles, 2018-2032 (tons).
Table 153. Companies developing nanocellulose products in textiles and apparel.
Table 154. Market overview for cellulose nanofibers in medicine and healthcare.
Table 155. Scorecard for cellulose nanofibers in medicine and healthcare.
Table 156. Market assessment for cellulose nanofibers in medicine and healthcare-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading, main global medicine and healthcare OEMs.
Table 157. Global demand for cellulose nanofibers in medical and healthcare, 2018-2032 (tons).
Table 158. Cellulose nanofibers product developers in medicine and healthcare.
Table 159. Market overview for cellulose nanofibers in the hygiene and sanitary products market.
Table 160. Global demand for cellulose nanofibers in hygiene, 2018-2032 (tons).
Table 161. Cellulose nanofibers product developers in hygiene and sanitary products.
Table 162. Market overview for cellulose nanofibers in paints and coatings.
Table 163. Scorecard for cellulose nanofibers in paints and coatings.
Table 164. Market assessment for cellulose nanofibers in paints and coatings-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading, main global paints and coatings OEMs.
Table 165. Global demand for cellulose nanofibers in paint and coatings, 2018-2032 (tons).
Table 166. Companies developing cellulose nanofibers products in paints and coatings, applications targeted and stage of commercialization.
Table 167. Market overview for cellulose nanofibers in aerogels.
Table 168. Scorecard for cellulose nanofibers in aerogels.
Table 169. Market assessment for cellulose nanofibers in aerogels-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading, main global aerogels OEMs.
Table 170. Global demand for cellulose nanofibers in aerogels, 2018-2032 (tons).
Table 171. Cellulose nanofibers product developers in aerogels.
Table 172. Market overview for cellulose nanofibers in oil and gas.
Table 173. Scorecard for cellulose nanofibers in oil and gas.
Table 174. Market assessment for cellulose nanofibers in oil and gas-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading, main global oil and gas OEMs.
Table 175. Global demand for cellulose nanofibers in the oil and gas market, 2018-2032 (tons).
Table 176. Cellulose nanofibers product developers in oil and gas exploration.
Table 177. CNF membranes.
Table 178. Market overview for cellulose nanofibers in filtration.
Table 179. Scorecard for cellulose nanofibers in filtration.
Table 180. Market assessment for cellulose nanofibers in filtration-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading, main global filtration OEMs.
Table 181: Global demand for cellulose nanofibers in the filtration market, 2018-2032 (tons).
Table 182. Companies developing cellulose nanofibers products in filtration.
Table 183. Market overview for cellulose nanofibers in rheology modifiers.
Table 184. Scorecard for cellulose nanofibers in rheology modifiers.
Table 185. Market assessment for cellulose nanofibers in rheology modifiers-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading, main global rheology modifier OEMs.
Table 186. Global demand for cellulose nanofibers in the rheology modifiers market, 2018-2032 (tons).
Table 187. Commercial activity in cellulose nanofibers rheology modifiers.
Table 188. Properties of flexible electronics?cellulose nanofiber film (nanopaper).
Table 189. Market assessment for cellulose nanofibers in printed, stretchable and flexible electronics-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading, main global printed, flexible and stretchable electronics OEMs.
Table 190. Companies developing cellulose nanofiber products in printed, stretchable and flexible electronics.
Table 191. Market assessment for cellulose nanofibers in 3D priniting-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading, main global 3D printing OEMs.
Table 192. Companies developing cellulose nanofibers 3D printing products.
Table 193. Market assessment for cellulose nanofibers in aerospace-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks, competing materials, material loading.
Table 194: Companies developing cellulose nanofibers products in aircraft and aerospace.
Table 195. Market assessment for cellulose nanofibers in Batteries-application, key benefits and motivation for use, megatrends, market drivers, technology drawbacks.
Table 196: Granbio Nanocellulose Processes.
Table 197. Nippon Paper commercial CNF products.
Table 198: Oji Holdings CNF products.

LIST OF FIGURES

Figure 1. Manufacturing process of PAN type carbon fibers.
Figure 2. Production processes for pitch-based carbon fibers.
Figure 3. Lignin/celluose precursor.
Figure 4. Process of preparing CF from lignin.
Figure 5. Carbon fiber manufacturing capacity in 2021, by company (metric tonnes)
Figure 6. ASIO drone by Flybotix.
Figure 7. Global demand for carbon fibers 2016-2032, in aerospace (metric tonnes).
Figure 8. Global revenues for CFRP 2016-2032, in aerospace (billions USD).
Figure 9. Global demand for carbon fibers 2016-2032, in wind energy (metric tonnes).
Figure 10. Global revenues for CFRP 2016-2032, in wind energy (billions USD).
Figure 11. Global demand for carbon fibers 2016-2032, in sports & leisure (metric tonnes).
Figure 12. Global revenues for CFRP 2016-2032, in sports & leisure (billions USD).
Figure 13. Global demand for carbon fibers 2016-2032, in automotive (metric tonnes).
Figure 14. Global revenues for CFRP 2016-2032, in automotive (billions USD).
Figure 15. Schematic of a 700-bar Type-IV COPV for on-board FCV hydrogen storage.
Figure 16. CF pressure vessel for Hyundai Truck.
Figure 17. Global demand for carbon fibers 2016-2032, in pressure vessels (metric tonnes).
Figure 18. Global revenues for CFRP 2016-2032, in pressure vessels (billions USD).
Figure 19. Global demand for carbon fibers 2016-2032, in oil and gas (metric tonnes).
Figure 20. Global revenues for CFRP 2016-2032, in oil and gas (billions USD).
Figure 21. Global demand for carbon fibers 2016-2032, by market (metric tonnes).
Figure 22. Global market revenues for Carbon fiber reinforced polymers (CFRP) 2016-2032, by market (billion USD).
Figure 23. Global demand for carbon fibers 2018-2032, by region (thousand metric tonnes).
Figure 24. 9T Labs' Red Series.
Figure 25. 3D printed component.
Figure 26. Continuous carbon fiber part.
Figure 27. Speedland SL:PDX trail shoe incorporating carbon fiber plate.
Figure 28. Carbon 1 MK II.
Figure 29. CR-9 carbon fibre wheel.
Figure 30. The Continuous Kinetic Mixing system.
Figure 31. CBAM-2 3D printer.
Figure 32. Thermoplastic CFRP single aisle pressure bulkhead demonstrator.
Figure 33. Rein4ced carbon mountain bike hardtails.
Figure 34. Recycled carbon fibers obtained through the R3FIBER process.
Figure 35. Compression molded automotive floorboard.
Figure 36. Types of natural fibers.
Figure 37. Cotton production volume 2018-2032 (Million MT).
Figure 38. Kapok production volume 2018-2032 (MT).
Figure 39. Luffa cylindrica fiber.
Figure 40. Jute production volume 2018-2032 (Million MT).
Figure 41. Hemp fiber production volume 2018-2032 (Million MT).
Figure 42. Flax fiber production volume 2018-2032 (MT).
Figure 43. Ramie fiber production volume 2018-2032 (MT).
Figure 44. Kenaf fiber production volume 2018-2032 (MT).
Figure 45. Sisal fiber production volume 2018-2032 (MT).
Figure 46. Abaca fiber production volume 2018-2032 (MT).
Figure 47. Coir fiber production volume 2018-2032 (MILLION MT).
Figure 48. Banana fiber production volume 2018-2032 (MT).
Figure 49. Pineapple fiber.
Figure 50. Bamboo fiber production volume 2018-2032 (MILLION MT).
Figure 51. Typical structure of mycelium-based foam.
Figure 52. Commercial mycelium composite construction materials.
Figure 53. BLOOM masterbatch from Algix.
Figure 54. Hemp fibers combined with PP in car door panel.
Figure 55. Car door produced from Hemp fiber.
Figure 56. Mercedes-Benz components containing natural fibers.
Figure 57. AlgiKicks sneaker, made with the Algiknit biopolymer gel.
Figure 58. Coir mats for erosion control.
Figure 59. Global fiber production in 2020, by fiber type, million MT and %.
Figure 60. Global fiber production (million MT) to 2020-2032.
Figure 61. Plant-based fiber production 2018-2032, by fiber type, MT.
Figure 62. Animal based fiber production 2018-2032, by fiber type, million MT.
Figure 63. Pluumo.
Figure 64. Algiknit yarn.
Figure 65. Amadou leather shoes.
Figure 66. Anpoly cellulose nanofiber hydrogel.
Figure 67. MEDICELLU™.
Figure 68. Roof frame made of natural fiber.
Figure 69. Beyond Leather Materials product.
Figure 70. Natural fibres racing seat.
Figure 71. Cellugy materials.
Figure 72. CuanSave film.
Figure 73. Mushroom leather.
Figure 74. Filler Bank CNC products.
Figure 75. Fibers on kapok tree and after processing.
Figure 76. CNF gel.
Figure 77. Block nanocellulose material.
Figure 78. CNF products developed by Hokuetsu.
Figure 79. Marine leather products.
Figure 80. BioFlex process.
Figure 81. MOGU-Wave panels.
Figure 82. Reishi.
Figure 83. Leather made from leaves.
Figure 84. Nike shoe with beLEAF™.
Figure 85. Lyocell process.
Figure 86. North Face Spiber Moon Parka.
Figure 87. Spider silk production.
Figure 88. Sulapac cosmetics containers.
Figure 89. Vegea production process.
Figure 90. Worn Again products.
Figure 91: Global revenues for nanofibers, by market 2018-2032, million USD.
Figure 92: Global revenues for nanofibers by region 2018-2032 (million USD).
Figure 93. Electrospun polyacrylonitrile (PAN) nanofibers with different orientation: a) aligned and b) random.
Figure 94. Electrospinning technique.
Figure 95. Scanning electron microscope images of electrospun nanofibers collected on different geometries and styles.
Figure 96. Typical electrospinning component schematic.
Figure 97. A multi-nozzle electrospinning device.
Figure 98. Schematic of a needle-free electrospinning system.
Figure 99 Electrohydrodynamic writing of nanofibers.
Figure 100. Electrospray Deposition Method.
Figure 101 Centrifugal jet spinning of nanofibers.
Figure 102. Schematic illustration of the centrifugal multispinning polymer nanofiber production process.
Figure 103 Solution blow spinning of nanofibers.
Figure 104. Conventional Filter Media.
Figure 105. Nanofiber coated filter media.
Figure 106. Ultra-web ® filter media by the Donaldson company.
Figure 107. Schematic of nanofiber membrane for seawater distillation.
Figure 108. Virus deactivating nanofiber membrane schematic.
Figure 109: Global revenues for nanofibers in the filter media market, 2018-2032 (million USD).
Figure 110: nanofiber conductive shirt.
Figure 111: Global revenues for nanofibers in the textiles market, 2018-2032 (millions USD).
Figure 112: Global revenues for nanofibers in the medical and healthcare market, 2018-2032 (million USD).
Figure 113. Comparison with conventional water treatment.
Figure 114. Nanoceram pleated filter cartridges.
Figure 115. Ultra-web ® filter media by the Donaldson company.
Figure 116. Nanospider™.
Figure 117. Nanofiber Nonwoven Fabrics from Hirose.
Figure 118. activLayr Bioactive Skincare Collagen product.
Figure 119. Spincare system.
Figure 120. ReSpimask® mask.
Figure 121. Schematic of nanofiber filter.
Figure 122. Sample sock made with Nanofront® recycled-polyester nanofiber.
Figure 123. Hitoe™ conductive nanofiber garment.
Figure 124. Schematic diagram of partial molecular structure of cellulose chain with numbering for carbon atoms and n= number of cellobiose repeating unit.
Figure 125. Scale of cellulose materials.
Figure 126. Types of nanocellulose.
Figure 127. Relationship between different kinds of nanocelluloses.
Figure 128. CNF gel.
Figure 129. TEM image of cellulose nanocrystals.
Figure 130. CNC preparation.
Figure 131. Extracting CNC from trees.
Figure 132. CNC slurry.
Figure 133. Nanocellulose preparation methods and resulting materials.
Figure 134. Various preparation methods for nanocellulose.
Figure 135. Applications of cellulose nanofibers in composites.
Figure 136. Global market demand for cellulose nanofibers in composites, 2018-2032 (metric tonnes).
Figure 137. CNF mixed PLA (Poly Lactic Acid).
Figure 138. CNF resin products.
Figure 139. Interior of NCV concept car.
Figure 140. Applications of cellulose nanofibers in automotive.
Figure 141. Interior of the NCV prototype.
Figure 142. Global demand for cellulose nanofibers in the automotive sector, 2018-2032 (tons).
Figure 143: Daio Paper's cellulose nanofiber material in doors and hood of race car.
Figure 144: CNF composite.
Figure 145: Engine cover utilizing Kao CNF composite resins.
Figure 146. CNF car engine cover developed in Japan Ministry of the Environment’s (MOE) Nano Cellulose Vehicle (NCV) Project.
Figure 147. Comparison of nanofillers with supplementary cementitious materials and aggregates in concrete.
Figure 148. Applications of cellulose nanofibers in construction.
Figure 149. Demand for cellulose nanofibers in construction, 2018-2032 (tons).
Figure 150. Applications of cellulose nanofibers in paper and board packaging.
Figure 151. Global demand for cellulose nanofibers in the paper & board/packaging, 2018-2032 (tons).
Figure 152. Applications of cellulose nanofibers in textiles and apparel.
Figure 153. Asics GEL-KAYANO™ 25 running shoe.
Figure 154. Demand for cellulose nanofibers in the textiles, 2018-2032 (tons).
Figure 155. CNF deodorant products.
Figure 156. Applications of cellulose nanofibers in medicine and healthcare.
Figure 157. Global demand for cellulose nanofibers in medical and healthcare, 2018-2032 (tons).
Figure 158. Fibnano.
Figure 159. Global demand for cellulose nanofibers in hygiene, 2018-2032 (tons).
Figure 160. Applications of cellulose nanofibers in paints and coatings.
Figure 161. Global demand for cellulose nanofibers in paint and coatings, 2018-2032 (tons).
Figure 162. Hefcel-coated wood (left) and untreated wood (right) after 30 seconds flame test.
Figure 163: Global demand for cellulose nanofibers in aerogels, 2018-2032 (tons).
Figure 164. Global demand for cellulose nanofibers in the oil and gas market, 2018-2032 (tons).
Figure 165. Nanocellulose sponge developed by EMPA for potential applications in oil recovery.
Figure 166. Applications of cellulose nanofibers in filtration.
Figure 167. Global demand for cellulose nanofibers in the filtration market, 2018-2032 (tons).
Figure 168. Multi-layered cross section of CNF-nw.
Figure 169. Applications of cellulose nanofibers in rheology modifiers.
Figure 170. Global demand for cellulose nanofibers in the rheology modifiers market, 2018-2032 (tons).
Figure 171. 'SURISURI' products.
Figure 172. Foldable nanopaper antenna.
Figure 173: Flexible electronic substrate made from CNF.
Figure 174. Oji CNF transparent sheets.
Figure 175. Electronic components using NFC as insulating materials.
Figure 176: Anpoly cellulose nanofiber hydrogel.
Figure 177. MEDICELLU™.
Figure 178: Ashai Kasei CNF production process.
Figure 179: Asahi Kasei CNF fabric sheet.
Figure 180: Properties of Asahi Kasei cellulose nanofiber nonwoven fabric.
Figure 181. CNF nonwoven fabric.
Figure 182. Borregaard Chemcell CNF production process.
Figure 183. nanoforest products.
Figure 184. Chuetsu Pulp & Paper CNF production process.
Figure 185. nanoforest-S.
Figure 186. nanoforest-PDP.
Figure 187. nanoforest-MB.
Figure 188. Daicel Corporation CNF production process.
Figure 189. Celish.
Figure 190: Trunk lid incorporating CNF.
Figure 191. Daio Paper CNF production process.
Figure 192. ELLEX products.
Figure 193. CNF-reinforced PP compounds.
Figure 194. Kirekira! toilet wipes.
Figure 195. Color CNF.
Figure 196. DIC Products CNF production process.
Figure 197. DKS Co. Ltd. CNF production process.
Figure 198: Rheocrysta spray.
Figure 199. DKS CNF products.
Figure 200: CNF based on citrus peel.
Figure 201. Citrus cellulose nanofiber.
Figure 202. Imerys CNF production process.
Figure 203. Filler Bank CNC products.
Figure 204: Cellulose Nanofiber (CNF) composite with polyethylene (PE).
Figure 205: CNF products from Furukawa Electric.
Figure 206. Granbio CNF production process.
Figure 207: Cutlery samples (spoon, knife, fork) made of nano cellulose and biodegradable plastic composite materials.
Figure 208. Non-aqueous CNF dispersion 'Senaf' (Photo shows 5% of plasticizer).
Figure 209: CNF gel.
Figure 210: Block nanocellulose material.
Figure 211: CNF products developed by Hokuetsu.
Figure 212. Innventia CNF production process.
Figure 213: Innventia AB movable nanocellulose demo plant.
Figure 214. Kami Shoji CNF products.
Figure 215. Dual Graft System.
Figure 216: Engine cover utilizing Kao CNF composite resins.
Figure 217. Acrylic resin blended with modified CNF (fluid) and its molded product (transparent film), and image obtained with AFM (CNF 10wt% blended).
Figure 218: 0.3% aqueous dispersion of sulfated esterified CNF and dried transparent film (front side).
Figure 219. Kruger Biomaterials, Inc. CNF production process.
Figure 220. CNF deodorant.
Figure 221. Chitin nanofiber product.
Figure 222. Marusumi Paper cellulose nanofiber products.
Figure 223. FibriMa cellulose nanofiber powder.
Figure 224. Cellulomix production process.
Figure 225. Nanobase versus conventional products.
Figure 226. Uni-ball Signo UMN-307.
Figure 227: CNF slurries.
Figure 228. Range of CNF products.
Figure 229: Nanocell serum product.
Figure 230: Hydrophobization facilities for raw pulp.
Figure 231: Mixing facilities for CNF-reinforced plastic.
Figure 232. Nippon Paper CNF production process.
Figure 233: Nippon Paper Industries’ adult diapers.
Figure 234. All-resin forceps incorporating CNF.
Figure 235. CNF paint product.
Figure 236: CNF wet powder.
Figure 237: CNF transparent film.
Figure 238: Transparent CNF sheets.
Figure 239. Oji Paper CNF production process.
Figure 240: CNF clear sheets.
Figure 241. Oji Holdings CNF polycarbonate product.
Figure 242: Fluorene cellulose ® powder.
Figure 243. A vacuum cleaner part made of cellulose fiber (left) and the assembled vacuum cleaner.
Figure 244. Performance Biofilaments CNF production process.
Figure 245: XCNF.
Figure 246: CNF insulation flat plates.
Figure 247. Seiko PMC CNF production process.
Figure 248. Manufacturing process for STARCEL.
Figure 249: Rubber soles incorporating CNF.
Figure 250. CNF dispersion and powder from Starlite.
Figure 251. Stora Enso CNF production process.
Figure 252. Sugino Machine CNF production process.
Figure 253: High Pressure Water Jet Process.
Figure 254: 2 wt.? CNF suspension.
Figure 255. BiNFi-s Dry Powder.
Figure 256. BiNFi-s Dry Powder and Propylene (PP) Complex Pellet.
Figure 257: Silk nanofiber (right) and cocoon of raw material.
Figure 258: SVILOSA AD CNC products.
Figure 259: Silver / CNF composite dispersions.
Figure 260: CNF/nanosilver powder.
Figure 261: Comparison of weight reduction effect using CNF.
Figure 262: CNF resin products.
Figure 263. University of Maine CNF production process.
Figure 264. UPM-Kymmene CNF production process.
Figure 265. FibDex® wound dressing.
Figure 266. US Forest Service Products Laboratory CNF production process.
Figure 267: Flexible electronic substrate made from CNF.
Figure 268. VTT 100% bio-based stand-up pouches.
Figure 269. VTT CNF production process.
Figure 270: HefCel-coated wood (left) and untreated wood (right) after 30 seconds flame test.
Figure 271: Bio-based barrier bags prepared from Tempo-CNF coated bio-HDPE film.
Figure 272. S-CNF in powder form.
Figure 273. Zelfo Technology GmbH CNF production process.


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