The Global Market for Advanced Carbon Materials 2026-2036

TABLE OF CONTENTS

1 THE ADVANCED CARBON MATERIALS MARKET

• 1.1 Market overview
• 1.2 Market Landscape and Evolution
• 1.3 Key Market Drivers
  • 1.3.1 Electrification and Energy Storage
  • 1.3.2 Hydrogen Economy
  • 1.3.3 Renewable Energy Expansion
  • 1.3.4 Aerospace Recovery and Growth
  • 1.3.5 Digital Infrastructure and Electronics
  • 1.3.6 Carbon Capture, Utilisation, and Storage (CCUS)
  • 1.3.7 Carbon Removal and Sustainability Mandates
• 1.4 Main Applications
• 1.5 Role of Advanced Carbon Materials in the Green Transition
• 1.6 Main applications
  • 1.6.1 Thermal management
    • 1.6.1.1 Commercialization
  • 1.6.2 Conductive Battery Additives and Electrodes
  • 1.6.3 Composites
• 1.7 Role of advanced carbon materials in the green transition

2 CARBON FIBERS

• 2.1 Properties of carbon fibers
  • 2.1.1 Types by modulus
  • 2.1.2 Types by the secondary processing
• 2.2 Precursor material types
  • 2.2.1 PAN: Polyacrylonitrile
    • 2.2.1.1 Spinning
    • 2.2.1.2 Stabilizing
    • 2.2.1.3 Carbonizing
    • 2.2.1.4 Surface treatment
    • 2.2.1.5 Sizing
    • 2.2.1.6 Pitch-based carbon fibers
    • 2.2.1.7 Isotropic pitch
    • 2.2.1.8 Mesophase pitch
    • 2.2.1.9 Viscose (Rayon)-based carbon fibers
  • 2.2.2 Bio-based and alternative precursors
    • 2.2.2.1 Lignin
    • 2.2.2.2 Polyethylene
    • 2.2.2.3 Vapor grown carbon fiber (VGCF)
    • 2.2.2.4 Textile PAN
  • 2.2.3 Recycled carbon fibers (r-CF)
    • 2.2.3.1 The market for rCF
    • 2.2.3.2 Recycling processes
    • 2.2.3.3 Companies
  • 2.2.4 Carbon Fiber 3D Printing
  • 2.2.5 Plasma oxidation
  • 2.2.6 Carbon fiber reinforced polymer (CFRP)
    • 2.2.6.1 Applications
• 2.3 Markets and applications
  • 2.3.1 Aerospace
  • 2.3.2 Wind energy
  • 2.3.3 Sports & leisure
  • 2.3.4 Automotive
  • 2.3.5 Pressure vessels
  • 2.3.6 Oil and gas
  • 2.3.7 Civil Engineering and Infrastructure
• 2.4 Market analysis
  • 2.4.1 Market Growth Drivers and Trends
  • 2.4.2 Regulations
  • 2.4.3 Price and Costs Analysis
  • 2.4.4 Supply Chain
  • 2.4.5 Competitive Landscape
    • 2.4.5.1 Annual capacity, by producer
  • 2.4.6 Future Outlook
  • 2.4.7 Addressable Market Size
  • 2.4.8 Risks and Opportunities
  • 2.4.9 Global Carbon Fiber Demand 2020-2036
    • 2.4.9.1 By Industry (Thousand Metric Tonnes)
    • 2.4.9.2 By Region (Thousand Metric Tonnes)
    • 2.4.9.3 Revenues by Industry (Billions USD)
• 2.5 Company profiles
  • 2.5.1 Carbon fiber producers (28 company profiles)
  • 2.5.2 Carbon Fiber composite producers (62 company profiles)
  • 2.5.3 Carbon fiber recyclers (17 company profiles)

3 CARBON BLACK

• 3.1 Commercially available carbon black
• 3.2 Properties
  • 3.2.1 Particle size distribution
  • 3.2.2 Structure-Aggregate size
  • 3.2.3 Surface chemistry
  • 3.2.4 Agglomerates
  • 3.2.5 Colour properties
  • 3.2.6 Porosity
  • 3.2.7 Physical form
• 3.3 Manufacturing processes
• 3.4 Markets and applications
  • 3.4.1 Tires and automotive
  • 3.4.2 Non-Tire Rubber (Industrial rubber)
  • 3.4.3 Other markets
• 3.5 Specialty carbon black
  • 3.5.1 Global market size for specialty CB
• 3.6 Recovered carbon black (rCB)
  • 3.6.1 Pyrolysis of End-of-Life Tires (ELT)
  • 3.6.2 Discontinuous ("batch"#) pyrolysis
  • 3.6.3 Semi-continuous pyrolysis
  • 3.6.4 Continuous pyrolysis
  • 3.6.5 Key players
  • 3.6.6 Global market size for Recovered Carbon Black
• 3.7 Market analysis
  • 3.7.1 Market Growth Drivers and Trends
  • 3.7.2 Regulations
  • 3.7.3 Supply chain
  • 3.7.4 Price and Costs Analysis
    • 3.7.4.1 Feedstock
    • 3.7.4.2 Commercial carbon black
  • 3.7.5 Competitive Landscape
    • 3.7.5.1 Production capacities
  • 3.7.6 Future Outlook
  • 3.7.7 Customer Segmentation
  • 3.7.8 Addressable Market Size
  • 3.7.9 Risks and Opportunities
  • 3.7.10 Global market
    • 3.7.10.1 By end-user market (100,000 tons)
    • 3.7.10.2 By end-user market (billion USD)
    • 3.7.10.3 By region (100,000 tons)
• 3.8 Company profiles (53 company profiles)

4 GRAPHITE

• 4.1 Types of graphite
  • 4.1.1 Natural vs synthetic graphite
• 4.2 Natural graphite
  • 4.2.1 Classification
  • 4.2.2 Processing
  • 4.2.3 Flake
    • 4.2.3.1 Grades
    • 4.2.3.2 Applications
    • 4.2.3.3 Spherical graphite
    • 4.2.3.4 Expandable graphite
  • 4.2.4 Amorphous graphite
    • 4.2.4.1 Applications
  • 4.2.5 Crystalline vein graphite
    • 4.2.5.1 Applications
• 4.3 Synthetic graphite
  • 4.3.1 Classification
    • 4.3.1.1 Primary synthetic graphite
    • 4.3.1.2 Secondary synthetic graphite
  • 4.3.2 Processing
    • 4.3.2.1 Processing for battery anodes
  • 4.3.3 Issues with synthetic graphite production
  • 4.3.4 Isostatic Graphite
    • 4.3.4.1 Description
    • 4.3.4.2 Markets
    • 4.3.4.3 Producers and production capacities
  • 4.3.5 Graphite electrodes
  • 4.3.6 Extruded Graphite
  • 4.3.7 Vibration Molded Graphite
  • 4.3.8 Die-molded graphite
• 4.4 New technologies
• 4.5 Recycling of graphite materials
• 4.6 Markers and applications
• 4.7 Graphite pricing (ton)
  • 4.7.1 Pricing 2020-2025
    • 4.7.1.1 Fine Flake Graphite Prices
    • 4.7.1.2 Spherical Graphite Prices
    • 4.7.1.3 +32 Mesh Natural Flake Graphite Prices
    • 4.7.1.4 Large Flake
• 4.8 Global production of graphite
  • 4.8.1 Market Dynamics and Demand Drivers (2024-2025)
    • 4.8.1.1 Steel Sector Weakness
    • 4.8.1.2 Inventory Overhang Impact
    • 4.8.1.3 Substitution Dynamics
    • 4.8.1.4 Ex-China Markets Maintain Natural Preference
  • 4.8.2 China dominance
    • 4.8.2.1 Domestic Market Competition Structure
    • 4.8.2.2 Strategic Cost Optimization (2021-2024)
    • 4.8.2.3 Government Support and Subsidy Structures
    • 4.8.2.4 China's Strategic Export Control Framework
    • 4.8.2.5 Practical Impact of Export Controls
  • 4.8.3 United States Subsidies, Loans, and Tariff Policy Evolution
    • 4.8.3.1 Federal Loan Guarantee Programs
    • 4.8.3.2 The Inflation Reduction Act (IRA) and Clean Vehicle Credit (CVC)
    • 4.8.3.3 FEOC Restrictions and Timeline Extensions
    • 4.8.3.4 Political Uncertainty - "One Big Beautiful Bill" and CVC Expiration
    • 4.8.3.5 Tariff Policy Evolution
    • 4.8.3.6 July 2025 - Preliminary AD Determination
    • 4.8.3.7 Chinese Retaliatory Measures
    • 4.8.3.8 Policy Sustainability Analysis
  • 4.8.4 Global mine production and reserves of natural graphite
  • 4.8.5 Global graphite production in tonnes, 2024-2036
    • 4.8.5.1 Natural Graphite
    • 4.8.5.2 Synthetic Graphite
  • 4.8.6 Western Market Cost Competitiveness Analysis
    • 4.8.6.1 Ex-China Natural Anode Cost Structure
    • 4.8.6.2 Chinese Pricing as Competitive Floor
    • 4.8.6.3 Policy Support Mechanisms Bridging the Gap
    • 4.8.6.4 Alternative Competitive Strategies
• 4.9 Global market demand for graphite by end use market 2016-2036, tonnes
  • 4.9.1 Battery Market Dominance
  • 4.9.2 Steel/Refractories Sector
  • 4.9.3 Mature Industrial Markets
• 4.10 Demand by region
  • 4.10.1 Asia-Pacific
  • 4.10.2 North America
  • 4.10.3 Europe
  • 4.10.4 Brazil
• 4.11 Factors that aid graphite market growth
• 4.12 Factors that hinder graphite market growth
• 4.13 Main market players
  • 4.13.1 Natural graphite
  • 4.13.2 Synthetic graphite
• 4.14 Market supply chain
• 4.15 Lithium-ion batteries
  • 4.15.1 Gigafactories
  • 4.15.2 Anode material in electric vehicles
    • 4.15.2.1 Properties
    • 4.15.2.2 Market demand
    • 4.15.2.3 Global Anode Market Structure and Competitive Dynamics
  • 4.15.3 Recent trends in the automotive market and EVs
  • 4.15.4 Higher costs and tight supply
  • 4.15.5 Forecast for EVs
• 4.16 Refractory manufacturing (Steel market)
  • 4.16.1 Steel market trends and graphite growth
  • 4.16.2 Carbon Sources for refractories
  • 4.16.3 Electric arc furnaces in steelmaking
  • 4.16.4 Recarburising
• 4.17 Graphite Shapes
• 4.18 Electronics
  • 4.18.1 Thermal management
• 4.19 Fuel Cells
• 4.20 Nuclear
• 4.21 Lubricants
• 4.22 Friction materials
• 4.23 Flame retardants
• 4.24 Solar and wind turbines
• 4.25 Company profiles (103 company profiles)

5 BIOCHAR

• 5.1 What is biochar?
• 5.2 Carbon sequestration
• 5.3 Properties of biochar
• 5.4 Markets and applications
• 5.5 Biochar production
• 5.6 Feedstocks
• 5.7 Production processes
  • 5.7.1 Sustainable production
  • 5.7.2 Pyrolysis
    • 5.7.2.1 Slow pyrolysis
    • 5.7.2.2 Fast pyrolysis
  • 5.7.3 Gasification
  • 5.7.4 Hydrothermal carbonization (HTC)
  • 5.7.5 Torrefaction
  • 5.7.6 Equipment manufacturers
• 5.8 Carbon credits
  • 5.8.1 Overview
  • 5.8.2 Removal and reduction credits
  • 5.8.3 The advantage of biochar
  • 5.8.4 Price
  • 5.8.5 Buyers of biochar credits
  • 5.8.6 Competitive materials and technologies
    • 5.8.6.1 Geologic carbon sequestration
    • 5.8.6.2 Bioenergy with Carbon Capture and Storage (BECCS)
    • 5.8.6.3 Direct Air Carbon Capture and Storage (DACCS)
    • 5.8.6.4 Enhanced mineral weathering with mineral carbonation
    • 5.8.6.5 Ocean alkalinity enhancement
    • 5.8.6.6 Forest preservation and afforestation
• 5.9 Markets for biochar
  • 5.9.1 Agriculture & livestock farming
    • 5.9.1.1 Market drivers and trends
    • 5.9.1.2 Applications
  • 5.9.2 Construction materials
    • 5.9.2.1 Market drivers and trends
    • 5.9.2.2 Applications
  • 5.9.3 Wastewater treatment
    • 5.9.3.1 Market drivers and trends
    • 5.9.3.2 Applications
  • 5.9.4 Filtration
    • 5.9.4.1 Market drivers and trends
    • 5.9.4.2 Applications
  • 5.9.5 Carbon capture
    • 5.9.5.1 Market drivers and trends
    • 5.9.5.2 Applications
  • 5.9.6 Cosmetics
    • 5.9.6.1 Market drivers and trends
    • 5.9.6.2 Applications
  • 5.9.7 Textiles
    • 5.9.7.1 Market drivers and trends
    • 5.9.7.2 Applications
  • 5.9.8 Additive manufacturing
    • 5.9.8.1 Market drivers and trends
    • 5.9.8.2 Applications
  • 5.9.9 Ink
    • 5.9.9.1 Market drivers and trends
    • 5.9.9.2 Applications
  • 5.9.10 Polymers
    • 5.9.10.1 Market drivers and trends
    • 5.9.10.2 Applications
  • 5.9.11 Packaging
    • 5.9.11.1 Market drivers and trends
    • 5.9.11.2 Applications
  • 5.9.12 Steel and metal
    • 5.9.12.1 Market drivers and trends
    • 5.9.12.2 Applications
  • 5.9.13 Energy
    • 5.9.13.1 Market drivers and trends
    • 5.9.13.2 Applications
• 5.10 Market analysis
  • 5.10.1 Market Growth Drivers and Trends
  • 5.10.2 Regulations
  • 5.10.3 Price and Costs Analysis
  • 5.10.4 Supply Chain
  • 5.10.5 Competitive Landscape
  • 5.10.6 Future Outlook
  • 5.10.7 Customer Segmentation
  • 5.10.8 Addressable Market Size
  • 5.10.9 Risks and Opportunities
• 5.11 Global market
  • 5.11.1 By end use market
  • 5.11.2 By region
  • 5.11.3 By feedstocks
    • 5.11.3.1 China and Asia-Pacific
    • 5.11.3.2 North America
    • 5.11.3.3 Europe
    • 5.11.3.4 South America
    • 5.11.3.5 Africa
    • 5.11.3.6 Middle East
• 5.12 Company profiles (147 company profiles)

6 GRAPHENE

• 6.1 Types of graphene
• 6.2 Properties
• 6.3 Market analysis
  • 6.3.1 Market Growth Drivers and Trends
  • 6.3.2 Regulations
  • 6.3.3 Price and Costs Analysis
    • 6.3.3.1 Pristine graphene flakes pricing/CVD graphene
    • 6.3.3.2 Few-Layer graphene pricing
    • 6.3.3.3 Graphene nanoplatelets pricing
    • 6.3.3.4 Graphene oxide (GO) and reduced Graphene Oxide (rGO) pricing
    • 6.3.3.5 Multi-Layer graphene (MLG) pricing
    • 6.3.3.6 Graphene ink
  • 6.3.4 Markets and applications
    • 6.3.4.1 Batteries
    • 6.3.4.2 Supercapacitors
    • 6.3.4.3 Polymer additives
    • 6.3.4.4 Sensors
    • 6.3.4.5 Conductive inks
    • 6.3.4.6 Transparent conductive films
    • 6.3.4.7 Transistors and integrated circuits
    • 6.3.4.8 Filtration
    • 6.3.4.9 Thermal management
    • 6.3.4.10 Additive Manufacturing/3D printing
    • 6.3.4.11 Adhesives
    • 6.3.4.12 Aerospace
    • 6.3.4.13 Automotive
    • 6.3.4.14 Fuel cells
    • 6.3.4.15 Biomedical and healthcare
    • 6.3.4.16 Building and Construction
    • 6.3.4.17 Paints and coatings
    • 6.3.4.18 Photovoltaics
  • 6.3.5 Supply Chain
  • 6.3.6 Production Capacities
  • 6.3.7 Future Outlook
  • 6.3.8 Addressable Market Size
  • 6.3.9 Risks and Opportunities
  • 6.3.10 Global demand 2018-2036, tons
    • 6.3.10.1 Global demand by graphene material (tons)
    • 6.3.10.2 Global demand by end user market
    • 6.3.10.3 Graphene market, by region
• 6.4 Company profiles (359 company profiles)

7 CARBON NANOTUBES

• 7.1 Properties
  • 7.1.1 Comparative properties of CNTs
• 7.2 Multi-walled carbon nanotubes (MWCNTs)
  • 7.2.1 Properties
  • 7.2.2 Markets and applications
• 7.3 Single-walled carbon nanotubes (SWCNTs)
  • 7.3.1 Properties
  • 7.3.2 Markets and applications
• 7.4 Market Overview
  • 7.4.1 Multi-Walled Carbon Nanotubes (MWCNTs)
  • 7.4.2 Single-Walled Carbon Nanotubes (SWCNTs)
  • 7.4.3 Market Demand by End-Use Market (2020-2036)
• 7.5 Markets for Carbon Nanotubes
  • 7.5.1 Energy Storage
  • 7.5.2 Polymer Composites
  • 7.5.3 Electronics
  • 7.5.4 Thermal interface materials
  • 7.5.5 Construction
  • 7.5.6 Coatings
  • 7.5.7 Automotive
  • 7.5.8 Aerospace
  • 7.5.9 Others (Filtration, Sensors, Medical Devices, Lubricants, and Emerging Applications)
• 7.6 Company profiles (154 company profiles)
• 7.7 Other types
  • 7.7.1 Double-walled carbon nanotubes (DWNTs)
    • 7.7.1.1 Properties
    • 7.7.1.2 Applications
  • 7.7.2 Vertically aligned CNTs (VACNTs)
    • 7.7.2.1 Properties
    • 7.7.2.2 Applications
  • 7.7.3 Few-walled carbon nanotubes (FWNTs)
    • 7.7.3.1 Properties
    • 7.7.3.2 Applications
  • 7.7.4 Carbon Nanohorns (CNHs)
    • 7.7.4.1 Properties
    • 7.7.4.2 Applications
  • 7.7.5 Carbon Nano-Onions
    • 7.7.5.1 Properties
    • 7.7.5.2 Applications
    • 7.7.5.3 Production and Pricing
  • 7.7.6 Boron Nitride nanotubes (BNNTs)
    • 7.7.6.1 Properties
    • 7.7.6.2 Applications
    • 7.7.6.3 Production
  • 7.7.7 Companies (6 company profiles)

8 CARBON NANOFIBERS

• 8.1 Properties
• 8.2 Synthesis
  • 8.2.1 Chemical vapor deposition
  • 8.2.2 Electrospinning
  • 8.2.3 Template-based
  • 8.2.4 From biomass
• 8.3 Markets
  • 8.3.1 Energy storage
    • 8.3.1.1 Batteries
    • 8.3.1.2 Supercapacitors
    • 8.3.1.3 Fuel cells
  • 8.3.2 CO2 capture
  • 8.3.3 Composites
  • 8.3.4 Filtration
  • 8.3.5 Catalysis
  • 8.3.6 Sensors
  • 8.3.7 Electromagnetic Interference (EMI) Shielding
  • 8.3.8 Biomedical
  • 8.3.9 Concrete
• 8.4 Market analysis
  • 8.4.1 Market Growth Drivers and Trends
  • 8.4.2 Price and Costs Analysis
  • 8.4.3 Supply Chain
  • 8.4.4 Future Outlook
  • 8.4.5 Addressable Market Size
  • 8.4.6 Risks and Opportunities
• 8.5 Global market revenues
• 8.6 Companies (12 company profiles)

9 FULLERENES

• 9.1 Properties
• 9.2 Markets and applications
• 9.3 Technology Readiness Level (TRL)
• 9.4 Market analysis
  • 9.4.1 Market Growth Drivers and Trends
  • 9.4.2 Price and Costs Analysis
  • 9.4.3 Supply Chain
  • 9.4.4 Future Outlook
  • 9.4.5 Customer Segmentation
  • 9.4.6 Addressable Market Size
  • 9.4.7 Risks and Opportunities
  • 9.4.8 Global market demand
• 9.5 Producers (20 company profiles)

10 NANODIAMONDS

• 10.1 Introduction
• 10.2 Types
  • 10.2.1 Detonation Nanodiamonds
  • 10.2.2 Fluorescent nanodiamonds (FNDs)
  • 10.2.3 Diamond semiconductors
• 10.3 Markets and applications
• 10.4 Market analysis
  • 10.4.1 Market Growth Drivers and Trends
  • 10.4.2 Regulations
  • 10.4.3 Price and Costs Analysis
  • 10.4.4 Supply Chain
  • 10.4.5 Future Outlook
  • 10.4.6 Risks and Opportunities
  • 10.4.7 Global demand 2018-2036, tonnes
• 10.5 Company profiles (30 company profiles)

11 GRAPHENE QUANTUM DOTS

• 11.1 Comparison to quantum dots
• 11.2 Properties
• 11.3 Synthesis
  • 11.3.1 Top-down method
  • 11.3.2 Bottom-up method
• 11.4 Applications
• 11.5 Graphene quantum dots pricing
• 11.6 Graphene quantum dot producers (9 company profiles)

12 CARBON FOAM

• 12.1 Types
  • 12.1.1 Carbon aerogels
    • 12.1.1.1 Carbon-based aerogel composites
• 12.2 Properties
• 12.3 Markets and Applications
• 12.4 Company profiles (10 company profiles)

13 DIAMOND-LIKE CARBON (DLC) COATINGS

• 13.1 Properties
• 13.2 Applications and markets
• 13.3 Global market size
• 13.4 Company profiles (9 company profiles)

14 ACTIVATED CARBON

• 14.1 Overview
• 14.2 Types
  • 14.2.1 Powdered Activated Carbon (PAC)
  • 14.2.2 Granular Activated Carbon (GAC)
  • 14.2.3 Extruded Activated Carbon (EAC)
  • 14.2.4 Impregnated Activated Carbon
  • 14.2.5 Bead Activated Carbon (BAC)
  • 14.2.6 Polymer Coated Carbon
• 14.3 Production
  • 14.3.1 Coal-based Activated Carbon
  • 14.3.2 Wood-based Activated Carbon
  • 14.3.3 Coconut Shell-based Activated Carbon
  • 14.3.4 Fruit Stone and Nutshell-based Activated Carbon
  • 14.3.5 Polymer-based Activated Carbon
  • 14.3.6 Activated Carbon Fibers (ACFs)
• 14.4 Markets and applications
  • 14.4.1 Water Treatment
  • 14.4.2 Air Purification
  • 14.4.3 Food and Beverage Processing
  • 14.4.4 Pharmaceutical and Medical Applications
  • 14.4.5 Chemical and Petrochemical Industries
  • 14.4.6 Mining and Precious Metal Recovery
  • 14.4.7 Environmental Remediation
• 14.5 Market analysis
  • 14.5.1 Market Growth Drivers and Trends
  • 14.5.2 Regulations
  • 14.5.3 Price and Costs Analysis
  • 14.5.4 Supply Chain
  • 14.5.5 Future Outlook
  • 14.5.6 Customer Segmentation
  • 14.5.7 Addressable Market Size
  • 14.5.8 Risks and Opportunities
• 14.6 Global market revenues 2020-2036
• 14.7 Companies (22 company profiles)

15 CARBON AEROGELS AND XEROGELS

• 15.1 Overview
• 15.2 Types
  • 15.2.1 Resorcinol-Formaldehyde (RF) Carbon Aerogels and Xerogels
  • 15.2.2 Phenolic-Furfural (PF) Carbon Aerogels and Xerogels
  • 15.2.3 Melamine-Formaldehyde (MF) Carbon Aerogels and Xerogels
  • 15.2.4 Biomass-derived Carbon Aerogels and Xerogels
  • 15.2.5 Doped Carbon Aerogels and Xerogels
  • 15.2.6 Composite Carbon Aerogels and Xerogels
• 15.3 Markets and applications
  • 15.3.1 Energy Storage
  • 15.3.2 Thermal Insulation
  • 15.3.3 Catalysis
  • 15.3.4 Environmental Remediation
  • 15.3.5 Other Applications
• 15.4 Market analysis
  • 15.4.1 Market Growth Drivers and Trends
  • 15.4.2 Regulations
  • 15.4.3 Price and Costs Analysis
  • 15.4.4 Supply Chain
  • 15.4.5 Future Outlook
  • 15.4.6 Customer Segmentation
  • 15.4.7 Addressable Market Size
  • 15.4.8 Risks and Opportunities
• 15.5 Global market
• 15.6 Companies (10 company profiles)

16 CARBON MATERIALS FROM CARBON CAPTURE AND UTILIZATION

• 16.1 CO2 capture from point sources
  • 16.1.1 Transportation
  • 16.1.2 Global point source CO2 capture capacities
• 16.2 Main carbon capture processes
  • 16.2.1 Materials
  • 16.2.2 Post-combustion
  • 16.2.3 Oxy-fuel combustion
  • 16.2.4 Liquid or supercritical CO2: Allam-Fetvedt Cycle
  • 16.2.5 Pre-combustion
• 16.3 Carbon separation technologies
  • 16.3.1 Absorption capture
  • 16.3.2 Adsorption capture
  • 16.3.3 Membranes
  • 16.3.4 Liquid or supercritical CO2 (Cryogenic) capture
  • 16.3.5 Chemical Looping-Based Capture
  • 16.3.6 Calix Advanced Calciner
  • 16.3.7 Other technologies
    • 16.3.7.1 Solid Oxide Fuel Cells (SOFCs)
  • 16.3.8 Comparison of key separation technologies
  • 16.3.9 Electrochemical conversion of CO2
    • 16.3.9.1 Process overview
• 16.4 Direct air capture (DAC)
  • 16.4.1 Description
• 16.5 Companies (4 company profiles)

17 RESEARCH METHODOLOGY

18 REFERENCES

List of Tables

• Table 1. Advanced Carbon Materials Market 2024-2036 (Billions USD)
• Table 2. The advanced carbon materials market.
• Table 3. Applications and Properties of Carbon Materials in Thermal Management for IC/Chip Manufacturing.
• Table 4. Companies and Products Utilizing Carbon Materials in Thermal Management for IC/Chip Manufacturing.
• Table 5.Carbon-Based Thermal Management Materials
• Table 6. Carbon-Based Battery Additives
• Table 7. Classification and types of the carbon fibers.
• Table 8. Summary of carbon fiber properties.
• Table 9. Modulus classifications of carbon fiber.
• Table 10. Comparison of main precursor fibers.
• Table 11. Properties of lignins and their applications.
• Table 12. Lignin-derived anodes in lithium batteries.
• Table 13. Fiber properties of polyolefin-based CFs.
• Table 14. Summary of carbon fiber (CF) recycling technologies. Advantages and disadvantages.
• Table 15. Retention rate of tensile properties of recovered carbon fibres by different recycling processes.
• Table 16. Recycled carbon fiber producers, technology and capacity.
• Table 17. Methods for direct fiber integration.
• Table 18. Continuous fiber 3D printing producers.
• Table 19. Summary of markets and applications for CFRPs.
• Table 20. Comparison of CFRP to competing materials.
• Table 21. The market for carbon fibers in wind energy-market drivers, applications, desirable properties, pricing and key players.
• Table 22. The market for carbon fibers in sports & leisure-market drivers, applications, desirable properties, pricing and key players.
• Table 23. The market for carbon fibers in automotive-market drivers, applications, desirable properties, pricing and key players.
• Table 24. The market for carbon fibers in pressure vessels-market drivers, desirable properties of CF, applications, pricing, key players.
• Table 25. The market for carbon fibers in oil and gas-market drivers, desirable properties, applications, pricing and key players.
• Table 26. Market drivers and trends in carbon fibers.
• Table 27. Regulations pertaining to carbon fibers
• Table 28. Price and costs analysis for carbon fibers.
• Table 29. Carbon fibers supply chain.
• Table 30. Production capacities of carbon fiber producers, in metric tonnes, current and planned.
• Table 31. Future Outlook by End-Use Market.
• Table 32. Addressable market size for carbon fibers by market.
• Table 33. Market challenges in the CF and CFRP market.
• Table 34. Global carbon fiber demand 2016-2036, by industry (MT).
• Table 35. Global Carbon Fiber Demand 2020-2036, by Region (Thousand Metric Tonnes)
• Table 36. Global Carbon Fiber Revenues 2020-2036, by Industry (Billions USD)
• Table 37. Main Toray production sites and capacities.
• Table 38. Commercially available carbon black grades.
• Table 39. Properties of carbon black and influence on performance.
• Table 40. Carbon black compounds.
• Table 41. Carbon black manufacturing processes, advantages and disadvantages.
• Table 42: Market drivers for carbon black in the tire industry.
• Table 43. Global market for carbon black in tires (Million metric tons), 2018 to 2036.
• Table 44. Carbon black non-tire applications.
• Table 45. Specialty carbon black demand, 2018-2036 (000s Tons), by market.
• Table 46. Categories for recovered carbon black (rCB) based on key properties and intended applications.
• Table 47. rCB post-treatment technologies.
• Table 48. Recovered carbon black producers.
• Table 49. Recovered carbon black demand, 2018-2036 (000s Tons), by market
• Table 50. Market Growth Drivers and Trends in Carbon Black.
• Table 51. Regulations pertaining to carbon black.
• Table 52. Market supply chain for carbon black.
• Table 53 Pricing of carbon black.
• Table 54. Carbon black capacities, by producer.
• Table 55. Future outlook for carbon black by end use market.
• Table 56. Customer Segmentation: Carbon Black.
• Table 57. Addressable market size for carbon black by market.
• Table 58. Risks and Opportunities in Carbon Black.
• Table 59. Global market for carbon black 2018-2036, by end-user market (100,000 tons)
• Table 60. Global market for carbon black 2018-2036, by end-user market (billion USD)
• Table 61. Global market for carbon black 2018-2036, by region (100,000 tons)
• Table 62. Selected physical properties of graphite.
• Table 63. Characteristics of natural and synthetic graphite.
• Table 64. Comparison between Natural and Synthetic Graphite.
• Table 65. Natural graphite size categories, their advantages, average prices, and applications.
• Table 66. Classification of natural graphite with its characteristics.
• Table 67. Applications of flake graphite.
• Table 68. Amorphous graphite applications.
• Table 69. Crystalline vein graphite applications.
• Table 70. Characteristics of synthetic graphite.
• Table 71: Main markets and applications of isostatic graphite.
• Table 72. Current or planned production capacities for isostatic graphite.
• Table 73. Main graphite electrode producers and capacities (MT/year).
• Table 74. Extruded graphite applications.
• Table 75. Applications of Vibration Molded Graphite.
• Table 76. Applicaitons of Die-molded graphite.
• Table 77. Recycled refractory graphite applications.
• Table 78. Markets and applications of graphite.
• Table 79. Pricing by Graphite Type, 2020-2025.
• Table 80. Fine Flake Graphite Prices (-100 mesh, 90-97% C).
• Table 81. Spherical Graphite Prices (99.95% C).
• Table 82. Spherical Graphite Quality Grades and Applications.
• Table 83. +32 Mesh Natural Flake Graphite Prices (>500micrometer, 94-97% C).
• Table 84. Large Flake Premium Analysis.
• Table 85. Graphite Pricing Compression Analysis 2022-2024.
• Table 86.Chinese Battery AAM Mix Evolution.
• Table 87. Chinese Graphite Anode Market Structure.
• Table 88. Chinese Graphitisation Cost Evolution 2021-2024.
• Table 89. Chinese Feedstock Cost Dynamics 2021-2024.
• Table 90. Examples of Graphite-Related Federal Support.
• Table 91. Potential Final Combined Tariffs (if affirmative final determinations).
• Table 92. Estimated global mine Production of natural graphite 2020-2025, by country (tons).
• Table 93. Global graphite production in tonnes, 2024-2036.
• Table 94. Natural Graphite Breakdown (2024 & 2036).
• Table 95. Synthetic Graphite Breakdown (2024 & 2036).
• Table 96. Typical cost breakdown for ex-China natural graphite AAM production (per tonne).
• Table 97. Synthetic Anode Cost Dynamics.
• Table 98. Ex-China Natural Anode Cost Structure Analysis.
• Table 99. Current and potential tariff structures.
• Table 100. US Graphite Tariff Evolution and Impact Analysis.
• Table 101. Landed Cost Impact (Chinese AAM @ US$5,000-7,000/t DDP China).
• Table 102. Competitive Positioning Analysis.
• Table 103. Global Graphite Demand by End-Use Market 2020-2036 (tonnes).
• Table 104. End Use Market Share Evolution.
• Table 105. Global Graphite Demand by Regional Market 2020-2036 (tonnes).
• Table 106. Asia-Pacific Graphite Demand by Application 2020-2036 (tonnes).
• Table 107. North America Graphite Demand by Application 2020-2036 (tonnes)
• Table 108. North America Supply vs Demand Balance (AAM only).
• Table 109. Europe Graphite Demand by Application 2020-2036 (tonnes)
• Table 110. Europe Supply vs Demand Gap (AAM, kt):
• Table 111. Brazil Graphite Demand by Application 2020-2036 (tonnes)
• Table 112. Brazil Supply-Demand Balance:
• Table 113. Main natural graphite producers.
• Table 114. Main synthetic graphite producers.
• Table 115. Key minerals in an EV battery.
• Table 116. Global Battery Demand by Chemistry and Anode Type (2024-2030).
• Table 117. Current and planned gigafactories.
• Table 118. Key Battery Anode Specifications.
• Table 119. Historical Anode Pricing Trends (DDP China).
• Table 120. Major Anode Producer Profiles and Competitive Positioning
• Table 121. Overview of thermal management materials.
• Table 122. Graphite production capacities by producer.
• Table 123. Next Resources graphite flake products.
• Table 124. Summary of key properties of biochar.
• Table 125. Biochar physicochemical and morphological properties
• Table 126. Markets and applications for biochar.
• Table 127. Biochar feedstocks-source, carbon content, and characteristics.
• Table 128. Biochar production technologies, description, advantages and disadvantages.
• Table 129. Comparison of slow and fast pyrolysis for biomass.
• Table 130. Comparison of thermochemical processes for biochar production.
• Table 131. Biochar production equipment manufacturers.
• Table 132. Competitive materials and technologies that can also earn carbon credits.
• Table 133. Biochar applications in agriculture and livestock farming.
• Table 134. Effect of biochar on different soil properties.
• Table 135. Fertilizer products and their associated N, P, and K content.
• Table 136. Application of biochar in construction.
• Table 137. Process and benefits of biochar as an amendment in cement .
• Table 138. Application of biochar in asphalt.
• Table 139. Biochar applications for wastewater treatment.
• Table 140. Biochar in carbon capture overview.
• Table 141. Biochar in cosmetic products.
• Table 142. Biochar in textiles.
• Table 143. Biochar in additive manufacturing.
• Table 144. Biochar in ink.
• Table 145. Biochar in packaging.
• Table 146. Companies using biochar in packaging.
• Table 147. Biochar in steel and metal.
• Table 148. Summary of applications of biochar in energy.
• Table 149. Market Growth Drivers and Trends in biochar.
• Table 150. Regulations pertaining to biochar.
• Table 151. Biochar supply chain.
• Table 152. Key players, manufacturing methods and target markets.
• Table 153. Future outlook for biochar by end use market.
• Table 154. Customer Segmentation for Biochar.
• Table 155. Addressable market size for biochar by market.
• Table 156. Risk and opportunities in Biochar.
• Table 157. Global demand for biochar 2018-2036 (1,000 tons), by market.
• Table 158. Global demand for biochar 2018-2036 (1,000 tons), by region.
• Table 159. Biochar production by feedstocks in China (1,000 tons), 2023-2036.
• Table 160. Biochar production by feedstocks in Asia-Pacific (1,000 tons), 2023-2036.
• Table 161. Biochar production by feedstocks in Asia-Pacific (excluding China) (1,000 tons), 2023-2036.
• Table 162. Biochar production by feedstocks in North America (1,000 tons), 2023-2036.
• Table 163. Biochar production by feedstocks in Europe (1,000 tons), 2023-2036.
• Table 164. Biochar production by feedstocks in Africa (1,000 tons), 2023-2036.
• Table 165. Biochar production by feedstocks in the Middle East (tons), 2023-2036
• Table 166. Various Forms of Graphene and Related Materials
• Table 167. Properties of graphene, properties of competing materials, applications thereof.
• Table 168. Market Growth Drivers and Trends in graphene.
• Table 169. Regulations pertaining to graphene.
• Table 170. Types of graphene and typical prices.
• Table 171. Pristine graphene flakes pricing by producer.
• Table 172. Few-layer graphene pricing by producer.
• Table 173. Graphene nanoplatelets pricing by producer.
• Table 174. Graphene Oxide (GO) and Reduced Graphene Oxide (rGO) Pricing by Producer (2025 Updated)
• Table 175. Multi-layer graphene pricing by producer.
• Table 176. Graphene ink pricing by producer.
• Table 177. Market and applications for graphene in automotive (20255-2036).
• Table 178. Graphene supply chain.
• Table 179. Graphene producer production capacities.
• Table 180. Future outlook for graphene by end use market.
• Table 181. Addressable market size for graphene by market.
• Table 182. Risks and Opportunities in Graphene.
• Table 183. Global graphene demand by type of graphene material, 2018-2036 (tons).
• Table 184. Global graphene demand by market, 2018-2036 (tons).
• Table 185. Global graphene demand, by region, 2018-2036 (tons).
• Table 186. Performance criteria of energy storage devices.
• Table 187. Typical properties of SWCNT and MWCNT.
• Table 188. Properties of CNTs and comparable materials.
• Table 189. Applications of MWCNTs.
• Table 190. Comparative properties of MWCNT and SWCNT.
• Table 191. Markets, benefits and applications of Single-Walled Carbon Nanotubes.
• Table 192. Updated MWCNT Production Capacity Table (2024/2025)
• Table 193. SWCNT Production Capacity (2024)
• Table 194. Market demand for carbon nanotubes by end-use market, 2020-2036 (metric tons)
• Table 195. Application roadmap for carbon nanotubes in energy storage, 2025-2036.
• Table 196. Application roadmap for carbon nanotubes in polymer composites, 2025-2036.
• Table 197. Application roadmap for carbon nanotubes in electronics, 2025-2036.
• Table 198. Application roadmap for carbon nanotubes in thermal interface materials, 2025-2036.
• Table 199. Application roadmap for carbon nanotubes in construction, 2025-2036.
• Table 200. Application roadmap for carbon nanotubes in coatings, 2025-2036.
• Table 201. Application roadmap for carbon nanotubes in automotive, 2025-2036.
• Table 202. Application roadmap for carbon nanotubes in aerospace, 2025-2036.
• Table 203. Application roadmap for carbon nanotubes in other end-use markets, 2025-2036.
• Table 204. Chasm SWCNT products.
• Table 205. Thomas Swan SWCNT production.
• Table 206. Properties of carbon nanotube paper.
• Table 207. Applications of Double-walled carbon nanotubes.
• Table 208. Markets and applications for Vertically aligned CNTs (VACNTs).
• Table 209. Markets and applications for few-walled carbon nanotubes (FWNTs).
• Table 210. Markets and applications for carbon nanohorns.
• Table 211. Comparative properties of BNNTs and CNTs.
• Table 212. Applications of BNNTs.
• Table 213. Carbon Nanofibers from Biomass Analysis.
• Table 214. Market Growth Drivers and Trends in Carbon Nanofibers.
• Table 215. Price and Cost Analysis for Carbon Nanofibers.
• Table 216. Carbon nanofibers supply chain.
• Table 217. Future outlook for CNFs by end use market.
• Table 218. Addressable market size for CNFs by market.
• Table 219. Risks and Opportunities Analysis for Carbon Nanofibers.
• Table 220. Global market revenues for carbon nanofibers 2020-2036 (millions USD), by market
• Table 221. Market overview for fullerenes-Selling grade particle diameter, usage, advantages, average price/ton, high volume applications, low volume applications and novel applications.
• Table 222. Types of fullerenes and applications.
• Table 223. Products incorporating fullerenes.
• Table 224. Markets, benefits and applications of fullerenes.
• Table 225. Market Growth Drivers and Trends in Fullerenes.
• Table 226. Price and costs analysis for Fullerenes.
• Table 227. Fullerenes supply chain.
• Table 228. Future outlook for Fullerenes by end use market.
• Table 229. Addressable market size for Fullerenes by market.
• Table 230. Risks and Opportunities Analysis.
• Table 231. Global market demand for fullerenes, 2018-2036 (tons).
• Table 232. Properties of nanodiamonds.
• Table 233. Summary of types of NDS and production methods-advantages and disadvantages.
• Table 234. Markets, benefits and applications of nanodiamonds.
• Table 235. Market Growth Drivers and Trends in Nanodiamonds.
• Table 236. Regulations pertaining to Nanodiamonds.
• Table 237. Price and costs analysis for Nanodiamonds.
• Table 238. Price of nanodiamonds by producer.
• Table 239. Nanodiamonds supply chain.
• Table 240. Future outlook for Nanodiamonds by end use market.
• Table 241. Risks and Opportunities in Nanodiamonds.
• Table 242. Demand for nanodiamonds (metric tonnes), 2018-2036.
• Table 243. Production methods, by main ND producers.
• Table 244. Adamas Nanotechnologies, Inc. nanodiamond product list.
• Table 245. Carbodeon Ltd. Oy nanodiamond product list.
• Table 246. Daicel nanodiamond product list.
• Table 247. FND Biotech Nanodiamond product list.
• Table 248. JSC Sinta nanodiamond product list.
• Table 249. Plasmachem product list and applications.
• Table 250. Ray-Techniques Ltd. nanodiamonds product list.
• Table 251. Comparison of ND produced by detonation and laser synthesis.
• Table 252. Comparison of graphene QDs and semiconductor QDs.
• Table 253. Advantages and disadvantages of methods for preparing GQDs.
• Table 254. Applications of graphene quantum dots.
• Table 255. Prices for graphene quantum dots.
• Table 256. Properties of carbon foam materials.
• Table 257. Applications of carbon foams.
• Table 258. Properties of Diamond-like carbon (DLC) coatings.
• Table 259. Applications and markets for Diamond-like carbon (DLC) coatings.
• Table 260. Global revenues for DLC coatings, 2018-2036 (Billion USD).
• Table 261. Markets and Applications for Activated Carbon.
• Table 262. Market Growth Drivers and Trends in Activated Carbon.
• Table 263. Regulations pertaining to Activated Carbon.
• Table 264. Price and costs analysis for Activated Carbon.
• Table 265. Activated Carbon supply chain.
• Table 266. Future outlook for Activated Carbon by end use market.
• Table 267. Addressable market size for Activated Carbon by market.
• Table 268. Risks and Opportunities in Activated Carbon.
• Table 269. Global market revenues for Activated Carbon 2020-2036 (millions USD), by market.
• Table 270. Markets and Applications for Carbon Aerogels and Xerogels.
• Table 271. Market Growth Drivers and Trends in Carbon Aerogels and Xerogels.
• Table 272. Regulations pertaining to Carbon Aerogels and Xerogels.
• Table 273. Price and costs analysis for Carbon Aerogels and Xerogels.
• Table 274. Carbon Aerogels and Xerogels supply chain.
• Table 275. Future outlook for Carbon Aerogels and Xerogels by end use market.
• Table 276. Addressable market size for Carbon Aerogels and Xerogels by market.
• Table 277. Risks and Opportunities in Carbon Aerogels.
• Table 278. Global market revenues for Carbon Aerogels and Xerogels 2020-2036 (millions USD), by market.
• Table 279. Point source examples.
• Table 280.Historical Growth of Global Operational CCS Capacity (2010-2025)
• Table 281.Global CCS Project Pipeline Status (2025)
• Table 282.Major Operational CCS Facilities Worldwide (2025)
• Table 283. Assessment of carbon capture materials
• Table 284. Chemical solvents used in post-combustion.
• Table 285. Commercially available physical solvents for pre-combustion carbon capture.
• Table 286. Main capture processes and their separation technologies.
• Table 287. Absorption methods for CO2 capture overview.
• Table 288. Commercially available physical solvents used in CO2 absorption.
• Table 289. Adsorption methods for CO2 capture overview.
• Table 290. Membrane-based methods for CO2 capture overview.
• Table 291. Comparison of main separation technologies.
• Table 292. CO2 derived products via electrochemical conversion-applications, advantages and disadvantages.
• Table 293. Advantages and disadvantages of DAC.

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. Neustark modular plant.
• Figure 6. CR-9 carbon fiber wheel.
• Figure 7. The Continuous Kinetic Mixing system.
• Figure 8. Chemical decomposition process of polyurethane foam.
• Figure 9. Electron microscope image of carbon black.
• Figure 10. Different shades of black, depending on the surface of Carbon Black.
• Figure 11. Structure- Aggregate Size/Shape Distribution.
• Figure 12. Surface Chemistry - Surface Functionality Distribution.
• Figure 13. Sequence of structure development of Carbon Black.
• Figure 14. Carbon Black pigment in Acrylonitrile butadiene styrene (ABS) polymer.
• Figure 15 Break-down of raw materials (by weight) used in a tire.
• Figure 16. Applications of specialty carbon black.
• Figure 17. Pyrolysis process: from ELT to rCB, oil, and syngas, and applications thereof.
• Figure 18. Nike Algae Ink graphic tee.
• Figure 19. Structure of graphite.
• Figure 20. Comparison of SEM micrographs of sphere-shaped natural graphite (NG; after several processing steps) and synthetic graphite (SG).
• Figure 21. Overview of graphite production, processing and applications.
• Figure 22. Flake graphite.
• Figure 23. Flake graphite production
• Figure 24. Amorphous graphite.
• Figure 25. Vein graphite.
• Figure 26: Isostatic pressed graphite.
• Figure 27. Global market for graphite EAFs, 2018-2036 (MT).
• Figure 28. Extruded graphite rod.
• Figure 29. Vibration Molded Graphite.
• Figure 30. Die-molded graphite products.
• Figure 31. Graphite market supply chain (battery market).
• Figure 32. 2 Graphite: Content and share of total cell weight, for common types of lithium-ion cells for battery-powered electric vehicles.
• Figure 33. Graphite as active anode material in lithium-ion cell.
• Figure 34. Schematic illustration of an EAF.
• Figure 35. Biochars from different sources, and by pyrolyzation at different temperatures.
• Figure 36. Compressed biochar.
• Figure 37. Biochar production diagram.
• Figure 38. Pyrolysis process and by-products in agriculture.
• Figure 39. Perennial ryegrass plants grown in clay soil with (Right) and without (Left) biochar.
• Figure 40. Biochar bricks.
• Figure 41. Biochar production by feedstocks in South America (1,000 tons), 2023-2036.
• Figure 42. Capchar prototype pyrolysis kiln.
• Figure 43. Made of Air's HexChar panels.
• Figure 44. Takavator.
• Figure 45. Graphene and its descendants: top right: graphene; top left: graphite = stacked graphene; bottom right: nanotube=rolled graphene; bottom left: fullerene=wrapped graphene.
• Figure 46. Applications Roadmap for Graphene in Batteries (2025-2036)
• Figure 47. Applications Roadmap for Graphene in Supercapacitors (2025-2036)
• Figure 48. Applications Roadmap for Graphene in Polymer Additives (2025-2036)
• Figure 49. Applications Roadmap for Graphene in Sensors (2025-2036)
• Figure 50. Applications roadmap for graphene in conductive inks (2025-2036).
• Figure 51. Applications roadmap for graphene in transparent conductive films and displays (2025-2036)
• Figure 52. Applications roadmap for graphene transistors (2025-2036).
• Figure 53. Applications roadmap for graphene filtration membranes (2025-2036)
• Figure 54. Applications roadmap for graphene in thermal management (2025-2036).
• Figure 55. Applications roadmap to 2035 for graphene in additive manufacturing.
• Figure 56. Applications roadmap for graphene in adhesives (2025-2036).
• Figure 57. Applications roadmap for graphene in aerospace (2205-2036).
• Figure 58. Applications roadmap for graphene in fuel cells (2025-2036)
• Figure 59. Applications roadmap for graphene in graphene in biomedical and healthcare (2025-2036).
• Figure 60. Applications roadmap for graphene in graphene in building and construction (2025-2036).
• Figure 61. Applications roadmap for graphene in graphene in paints and coatings (2025-2036).
• Figure 62. Applications roadmap for graphene in in photovoltaics.
• Figure 63. Graphene heating films.
• Figure 64. Graphene flake products.
• Figure 65. Printed graphene biosensors.
• Figure 66. Prototype of printed memory device.
• Figure 67. Brain Scientific electrode schematic.
• Figure 68. Graphene battery schematic.
• Figure 69. Dotz Nano GQD products.
• Figure 70. Graphene-based membrane dehumidification test cell.
• Figure 71. Proprietary atmospheric CVD production.
• Figure 72. InP/ZnS, perovskite quantum dots and silicon resin composite under UV illumination.
• Figure 73. Sensor surface.
• Figure 74. BioStamp nPoint.
• Figure 75. Nanotech Energy battery.
• Figure 76. Hybrid battery powered electrical motorbike concept.
• Figure 77. NAWAStitch integrated into carbon fiber composite.
• Figure 78. Schematic illustration of three-chamber system for SWCNH production.
• Figure 79. TEM images of carbon nanobrush.
• Figure 80. Test performance after 6 weeks ACT II according to Scania STD4445.
• Figure 81. Quantag GQDs and sensor.
• Figure 82. The Sixth Element graphene products.
• Figure 83. Thermal conductive graphene film.
• Figure 84. Talcoat graphene mixed with paint.
• Figure 85. T-FORCE CARDEA ZERO.
• Figure 86. AWN Nanotech water harvesting prototype.
• Figure 87. Large transparent heater for LiDAR.
• Figure 88. Carbonics, Inc.'s carbon nanotube technology.
• Figure 89. Schematic of a fluidized bed reactor which is able to scale up the generation of SWNTs using the CoMoCAT process.
• Figure 90. Fuji carbon nanotube products.
• Figure 91. Cup Stacked Type Carbon Nano Tubes schematic.
• Figure 92. CSCNT composite dispersion.
• Figure 93. Flexible CNT CMOS integrated circuits with sub-10 nanoseconds stage delays.
• Figure 94. Koatsu Gas Kogyo Co. Ltd CNT product.
• Figure 95. Carbon nanotube paint product.
• Figure 96. MEIJO eDIPS product.
• Figure 97. NAWACap.
• Figure 98. NAWAStitch integrated into carbon fiber composite.
• Figure 99. Schematic illustration of three-chamber system for SWCNH production.
• Figure 100. TEM images of carbon nanobrush.
• Figure 101. CNT film.
• Figure 102. HiPCO-R Reactor.
• Figure 103. Shinko Carbon Nanotube TIM product.
• Figure 104. Smell iX16 multi-channel gas detector chip.
• Figure 105. The Smell Inspector.
• Figure 106. Toray CNF printed RFID.
• Figure 107. Double-walled carbon nanotube bundle cross-section micrograph and model.
• Figure 108. Schematic of a vertically aligned carbon nanotube (VACNT) membrane used for water treatment.
• Figure 109. TEM image of FWNTs.
• Figure 110. Schematic representation of carbon nanohorns.
• Figure 111. TEM image of carbon onion.
• Figure 112. Schematic of Boron Nitride nanotubes (BNNTs). Alternating B and N atoms are shown in blue and red.
• Figure 113. Conceptual diagram of single-walled carbon nanotube (SWCNT) (A) and multi-walled carbon nanotubes (MWCNT) (B) showing typical dimensions of length, width, and separation distance between graphene layers in MWCNTs (Source: JNM).
• Figure 114. Carbon nanotube adhesive sheet.
• Figure 115. Solid Carbon produced by UP Catalyst.
• Figure 116. Technology Readiness Level (TRL) for fullerenes.
• Figure 117. Detonation Nanodiamond.
• Figure 118. DND primary particles and properties.
• Figure 119. Functional groups of Nanodiamonds.
• Figure 120. NBD battery.
• Figure 121. Neomond dispersions.
• Figure 122. Visual representation of graphene oxide sheets (black layers) embedded with nanodiamonds (bright white points).
• Figure 123. Green-fluorescing graphene quantum dots.
• Figure 124. Schematic of (a) CQDs and (c) GQDs. HRTEM images of (b) C-dots and (d) GQDs showing combination of zigzag and armchair edges (positions marked as 1-4).
• Figure 125. Graphene quantum dots.
• Figure 126. Top-down and bottom-up methods.
• Figure 127. Dotz Nano GQD products.
• Figure 128. InP/ZnS, perovskite quantum dots and silicon resin composite under UV illumination.
• Figure 129. Quantag GQDs and sensor.
• Figure 130. Schematic of typical microstructure of carbon foam: (a) open-cell, (b) closed-cell.
• Figure 131. Classification of DLC coatings.
• Figure 132. SLENTEX-R roll (piece).
• Figure 133. CNF gel.
• Figure 134. Block nanocellulose material.
• Figure 135. CO2 capture and separation technology.
• Figure 136. Post-combustion carbon capture process.
• Figure 137. Postcombustion CO2 Capture in a Coal-Fired Power Plant.
• Figure 138. Oxy-combustion carbon capture process.
• Figure 139. Liquid or supercritical CO2 carbon capture process.
• Figure 140. Pre-combustion carbon capture process.
• Figure 141. Amine-based absorption technology.
• Figure 142. Pressure swing absorption technology.
• Figure 143. Membrane separation technology.
• Figure 144. Liquid or supercritical CO2 (cryogenic) distillation.
• Figure 145. Process schematic of chemical looping.
• Figure 146. Calix advanced calcination reactor.
• Figure 147. Fuel Cell CO2 Capture diagram.
• Figure 148. Electrochemical CO2 reduction products.
• Figure 149. CO2 captured from air using liquid and solid sorbent DAC plants, storage, and reuse.
• Figure 150. Global CO2 capture from biomass and DAC in the Net Zero Scenario.