The global market size of Carbon Nanotubes (CNTs) was USD 877.8 million in 2021 and is expected to grow at a revenue CAGR of 14.9% during the forecast period, reaching USD 3,042.2 million by 2030. The increasing demand for CNTs from various industries, such as electronics, biotechnology, and biomedical, is driving the market growth. CNTs are used in the production of a wide range of products, including photovoltaics, sensors, semiconductor devices, displays, conductors, smart textiles, energy conversion devices, and EV batteries. The market growth is also fueled by the rapid technological advancements in nanotechnology and biotechnology, rising investment in R&D activities by private companies, and increasing demand for CNTs in various applications such as drug delivery, biosensors, neuron growth & regeneration, vascular stents, enzymes sheathe, and transfection of DNA.
CNTs have high adsorption capacity and are useful for purifying gasoline, contaminated wastewater, organic compounds, and other contaminants. They are also effective in air and water purification due to their high adsorption capacity. CNTs can be functionalized and deployed for the removal of harmful oxides of nitrogen, sulfur, ozone, and VOCs from various mediums. CNT-based air and water filtration devices have been developed to address the growing water crisis and provide clean drinking water.
In the medical field, CNTs show potential in regenerative medicine and artificial implants, including drug and biomolecule delivery, tumor imaging, and photothermal therapy. CNTs can target malignant tumor cells and have Enhanced Permeability Retention (EPR) effects on cancerous tissue. CNTs can also reduce pain caused by artificial implants, and they have high tensile strength, making them useful as bone substitutes that can shape the bone structure. CNT-based biosensing devices have enabled the development of highly sensitive electrochemical biosensors for early-stage detection of various diseases, such as cancer and photoacoustic imaging. CNT-based immunosensors are still in the early stages of development, and there are many challenges to overcome for successful commercialization.
The demand for carbon nanotubes (CNTs) in the production of lithium-ion batteries and surface heating systems is expected to boost the market's revenue growth. CNTs are chemically-bonded carbon atoms that can greatly enhance energy storage and heat transfer in lithium-ion batteries. Electric vehicle manufacturers use batteries made with CNTs due to their lightweight and greater conductivity. Additionally, CNTs have been introduced as intermediate layers in Lithium Sulphur (Li-S) batteries because of their superior flexibility, excellent electrical conductivity, and chemical stability. CNT-based barrier layers may be able to reduce lithium polysulfide shuttling. Moreover, nano heating and CNT technologies are used in manufacturing complex parts of EVs due to their lightweight and extended range capabilities. Researchers from Germany's Osnabrück University of Applied Sciences are developing a surface heating system for EVs using CNT technologies to increase their range for Osnatech GmbH. CNTs can also enhance the thermal stability, electrical conductivity, toughness, durability, weight reduction, and structural strength when added to other materials such as epoxy resin and are widely used by industrial manufacturers.
Furthermore, the increasing demand for CNT-derived products from the aerospace industry for manufacturing satellites and airplane body parts is driving revenue growth of the market. Government organizations such as NASA, ISRO, Israel Aerospace Industry (IAI), and others are investing in R&D activities for the development of CNT-based composites for aircraft applications, which will improve Lightning Strike Protection (LSP), shielding against Electromagnetic Interference (EMI), and also reduce the weight of the aircraft. NASA's US-COMP research institute is developing CNT composites that are three times stronger and lighter than current carbon fiber materials for next-generation manned spacecraft for Mars, which is developed by an MTU graduate student.
MWCNTs are predicted to have a rapid growth rate due to their high electrical conductivity, which makes them suitable for mixing with other insulating materials to improve conductivity. The technology category includes arc discharge, laser ablation method, Chemical Vapor Deposition (CVD), high-pressure carbon monoxide, CoMoCAT, floating catalyst, and others. Arc discharge is expected to have a fast growth rate due to its ability to produce complex components easily, and CVD is expected to grow steadily because of its high purity and yield.
The application category includes electronics & semiconductor, aerospace and defense, energy storage, structural composites, chemical materials, medical & pharmacy, and others. Electronics & semiconductor is expected to grow steadily due to the high demand from the component manufacturing industry, while medical & pharmacy is expected to have a rapid growth rate due to the potential of CNTs in delivering a wide range of diagnostic agents and their ability to transport anti-cancer drugs, proteins, and gene. CNTs have also shown promise as mediators for Photothermal Therapy (PTT) and Photodynamic Therapy (PDT) for destroying cancer cells.
In 2021, North America accounted for the largest revenue share and is expected to maintain a steady growth rate over the forecast period. The rising demand for CNT made with polymers that enhance the thermal, electrical, and mechanical properties of various products is driving market growth. Additionally, increasing funding from government research activities for the development of advanced, innovative, and more durable polymers and composites, particularly in the U.S. and Canada, is contributing to the growth of the market.
Europe is expected to register a steady revenue growth rate during the forecast period. This region's market growth is driven by the increasing application of CNTs in various industries such as energy, healthcare, and others. Moreover, countries in Europe have the largest demand for EVs due to a well-developed infrastructure and government incentives to reduce pollution from vehicles and promote green and sustainable development.
CNTs have high adsorption capacity and are useful for purifying gasoline, contaminated wastewater, organic compounds, and other contaminants. They are also effective in air and water purification due to their high adsorption capacity. CNTs can be functionalized and deployed for the removal of harmful oxides of nitrogen, sulfur, ozone, and VOCs from various mediums. CNT-based air and water filtration devices have been developed to address the growing water crisis and provide clean drinking water.
In the medical field, CNTs show potential in regenerative medicine and artificial implants, including drug and biomolecule delivery, tumor imaging, and photothermal therapy. CNTs can target malignant tumor cells and have Enhanced Permeability Retention (EPR) effects on cancerous tissue. CNTs can also reduce pain caused by artificial implants, and they have high tensile strength, making them useful as bone substitutes that can shape the bone structure. CNT-based biosensing devices have enabled the development of highly sensitive electrochemical biosensors for early-stage detection of various diseases, such as cancer and photoacoustic imaging. CNT-based immunosensors are still in the early stages of development, and there are many challenges to overcome for successful commercialization.
Market Dynamics
Driving Force: Increasing demand for manufacturing batteries and surface heating systems for Electric Vehicles (EVs)The demand for carbon nanotubes (CNTs) in the production of lithium-ion batteries and surface heating systems is expected to boost the market's revenue growth. CNTs are chemically-bonded carbon atoms that can greatly enhance energy storage and heat transfer in lithium-ion batteries. Electric vehicle manufacturers use batteries made with CNTs due to their lightweight and greater conductivity. Additionally, CNTs have been introduced as intermediate layers in Lithium Sulphur (Li-S) batteries because of their superior flexibility, excellent electrical conductivity, and chemical stability. CNT-based barrier layers may be able to reduce lithium polysulfide shuttling. Moreover, nano heating and CNT technologies are used in manufacturing complex parts of EVs due to their lightweight and extended range capabilities. Researchers from Germany's Osnabrück University of Applied Sciences are developing a surface heating system for EVs using CNT technologies to increase their range for Osnatech GmbH. CNTs can also enhance the thermal stability, electrical conductivity, toughness, durability, weight reduction, and structural strength when added to other materials such as epoxy resin and are widely used by industrial manufacturers.
Furthermore, the increasing demand for CNT-derived products from the aerospace industry for manufacturing satellites and airplane body parts is driving revenue growth of the market. Government organizations such as NASA, ISRO, Israel Aerospace Industry (IAI), and others are investing in R&D activities for the development of CNT-based composites for aircraft applications, which will improve Lightning Strike Protection (LSP), shielding against Electromagnetic Interference (EMI), and also reduce the weight of the aircraft. NASA's US-COMP research institute is developing CNT composites that are three times stronger and lighter than current carbon fiber materials for next-generation manned spacecraft for Mars, which is developed by an MTU graduate student.
Restraining Force: Concerns regarding the environmental impact of CNTs
However, the market's revenue growth is expected to be hampered due to strict regulatory guidelines imposed by various countries' governments on CNT due to its environmental impact. CNT is composed of nanoscale particles that are non-biodegradable, and once it contaminates the environment, it is challenging to remove. When mixed with air and soil, it is frequently washed into rivers and lakes, where it can cause health issues such as oxidative stress, inflammation, cell damage, and adverse effects on cell performance for both animals and humans. Nanoparticles can severely damage human kidneys, and blood sugar levels can rise as a result. In addition, the lack of CNT solubility in water, organic solvents, and aqueous medium has limited its application and is expected to hamper market revenue growth. Scientists are modifying the surface of CNT to improve water and biocompatibility to overcome this problem.Key Takeways:
The global carbon nanotubes market is classified based on product type, technology, and application. The product type category is divided into Single-Walled Carbon Nanotubes (SWCNTs) and Multi-Walled Carbon Nanotubes (MWCNTs). SWCNTs are expected to show a steady growth rate due to their beneficial properties such as high thermal conductivity, ballistic electronic transport, and their ability to enhance the conductive and mechanical characteristics of other materials.MWCNTs are predicted to have a rapid growth rate due to their high electrical conductivity, which makes them suitable for mixing with other insulating materials to improve conductivity. The technology category includes arc discharge, laser ablation method, Chemical Vapor Deposition (CVD), high-pressure carbon monoxide, CoMoCAT, floating catalyst, and others. Arc discharge is expected to have a fast growth rate due to its ability to produce complex components easily, and CVD is expected to grow steadily because of its high purity and yield.
The application category includes electronics & semiconductor, aerospace and defense, energy storage, structural composites, chemical materials, medical & pharmacy, and others. Electronics & semiconductor is expected to grow steadily due to the high demand from the component manufacturing industry, while medical & pharmacy is expected to have a rapid growth rate due to the potential of CNTs in delivering a wide range of diagnostic agents and their ability to transport anti-cancer drugs, proteins, and gene. CNTs have also shown promise as mediators for Photothermal Therapy (PTT) and Photodynamic Therapy (PDT) for destroying cancer cells.
Regional Analysis:
Regional analysis reveals that the global carbon nanotubes market is segmented into Asia Pacific, North America, Europe, and other regions. Asia Pacific is expected to experience rapid growth during the forecast period, driven by increasing use of carbon nanotubes in the electronics, semiconductor, and automotive industries. The region has emerged as a leading global producer of electronics, with government initiatives in countries such as India creating numerous opportunities for small and medium-sized companies. Moreover, emerging CNT applications such as superconductors and hydrogen storage offer opportunities for industry participants to invest in these areas. Additionally, startups such as NoPo Technologies and Nano-C are entering this regional market with various CNT products, contributing to market revenue growth.In 2021, North America accounted for the largest revenue share and is expected to maintain a steady growth rate over the forecast period. The rising demand for CNT made with polymers that enhance the thermal, electrical, and mechanical properties of various products is driving market growth. Additionally, increasing funding from government research activities for the development of advanced, innovative, and more durable polymers and composites, particularly in the U.S. and Canada, is contributing to the growth of the market.
Europe is expected to register a steady revenue growth rate during the forecast period. This region's market growth is driven by the increasing application of CNTs in various industries such as energy, healthcare, and others. Moreover, countries in Europe have the largest demand for EVs due to a well-developed infrastructure and government incentives to reduce pollution from vehicles and promote green and sustainable development.
Table of Contents
Chapter 1. Market Synopsis1.1. Market Definition
1.2. Research Scope & Premise
1.3. Methodology
1.4. Market Estimation Technique
Chapter 2. Executive Summary
2.1. Summary Snapshot, 2022-2030
Chapter 3. Indicative Metrics
Chapter 4. Carbon Nanotubes Market Segmentation & Impact Analysis
4.1. Carbon Nanotubes Market Material Segmentation Analysis
4.2. Industrial Outlook
4.2.1. Market indicators analysis
4.2.2. Market drivers’ analysis
4.2.2.1. Increasing application in end-use industries such as electrical & electronics
4.2.2.2. Rising demand for CNT for making Electric Vehicle (EV) batteries
4.2.2.3. Technological advancement in carbon nanotechnology
4.2.2.4. Increasing demand for lightweight and low carbon-emitting vehicles
4.2.3. Market restraints analysis
4.2.3.1. Availability of substitutes
4.2.3.2. Environmental concerns and health & safety issues
4.2.3.3. Stringent and time-consuming regulatory policies
4.3. Technological Insights
4.4. Regulatory Framework
4.5. Price trend Analysis
4.6. Customer Mapping
4.7. COVID-19 Impact Analysis
4.8. Global Recession Influence
Chapter 5. Carbon Nanotubes Market By Product Type Insights & Trends
5.1. Product Type Dynamics & Market Share, 2022 & 2030
5.2. Single-Walled Carbon Nanotubes (SWCNTs)
5.2.1. Market estimates and forecast, 2019-2030 (USD Million)
5.2.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
5.3. Multi-Walled Carbon Nanotubes (MWCNTs)
5.3.1. Market estimates and forecast, 2019-2030 (USD Million)
5.3.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
Chapter 6. Carbon Nanotubes Market By Technology Insights & Trends
6.1. Technology Dynamics & Market Share, 2022 & 2030
6.2. Arc Discharge
6.2.1. Market estimates and forecast, 2019-2030 (USD Million)
6.2.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
6.3. Laser Ablation Method
6.3.1. Market estimates and forecast, 2019-2030 (USD Million)
6.3.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
6.4. Chemical Vapor Deposition (CVD)
6.4.1. Market estimates and forecast, 2019-2030 (USD Million)
6.4.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
6.5. Catalytic CVD
6.5.1. Market estimates and forecast, 2019-2030 (USD Million)
6.5.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
6.6. High-Pressure Carbon Monoxide
6.6.1. Market estimates and forecast, 2019-2030 (USD Million)
6.6.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
6.7. CoMoCAT
6.7.1. Market estimates and forecast, 2019-2030 (USD Million)
6.7.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
6.8. Floating Catalyst
6.8.1. Market estimates and forecast, 2019-2030 (USD Million)
6.8.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
6.9. Others
6.9.1. Market estimates and forecast, 2019-2030 (USD Million)
6.9.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
Chapter 7. Carbon Nanotubes Market By Application Insights & Trends
7.1. Application Dynamics & Market Share, 2022 & 2030
7.2. Electronics & Semiconductor
7.2.1. Market estimates and forecast, 2019-2030 (USD Million)
7.2.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
7.3. Aerospace and Defense
7.3.1. Market estimates and forecast, 2019-2030 (USD Million)
7.3.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
7.4. Energy Storage
7.4.1. Market estimates and forecast, 2019-2030 (USD Million)
7.4.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
7.5. Structural Composites
7.5.1. Market estimates and forecast, 2019-2030 (USD Million)
7.5.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
7.6. Chemical Materials
7.6.1. Market estimates and forecast, 2019-2030 (USD Million)
7.6.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
7.7. Medical & Pharmacy
7.7.1. Market estimates and forecast, 2019-2030 (USD Million)
7.7.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
7.8. Others
7.8.1. Market estimates and forecast, 2019-2030 (USD Million)
7.8.2. Market estimates and forecast, By Region, 2019-2030 (USD Million)
Chapter 8. Carbon Nanotubes Market Regional Outlook
8.1. Carbon Nanotubes Market Share by Region, 2022 & 2030
8.2. North America
8.2.1. North America Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.2.2. North America Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.2.3. North America Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.2.4. North America Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.2.5. U.S.
8.2.5.1. U.S. Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.2.5.2. U.S. Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.2.5.3. U.S. Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.2.5.4. U.S. Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.2.6. Canada
8.2.6.1. Canada Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.2.6.2. Canada Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.2.6.3. Canada Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.2.6.4. Canada Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.2.7. Mexico
8.2.7.1. Mexico Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.2.7.2. Mexico Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.2.7.3. Mexico Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.2.7.4. Mexico Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.3. Europe
8.3.1. Europe Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.3.2. Europe Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.3.3. Europe Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.3.4. Europe Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.3.5. Germany
8.3.5.1. Germany Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.3.5.2. Germany Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.3.5.3. Germany Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.3.5.4. Germany Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.3.6. U.K.
8.3.6.1. U.K. Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.3.6.2. U.K. Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.3.6.3. U.K. Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.3.6.4. U.K. Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.3.7. France
8.3.7.1. France Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.3.7.2. France Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.3.7.3. France Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.3.7.4. France Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.3.8. Italy
8.3.8.1. Italy Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.3.8.2. Italy Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.3.8.3. Italy Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.3.8.4. Italy Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.3.9. Spain
8.3.9.1. Spain Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.3.9.2. Spain Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.3.9.3. Spain Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.3.9.4. Spain Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.3.10. Sweden
8.3.10.1. Sweden Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.3.10.2. Sweden Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.3.10.3. Sweden Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.3.10.4. Sweden Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.3.11. BENELUX
8.3.11.1. BENELUX Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.3.11.2. BENELUX Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.3.11.3. BENELUX Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.3.11.4. BENELUX Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.3.12. Rest of Europe
8.3.12.1. Rest of Europe Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.3.12.2. Rest of Europe Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.3.12.3. Rest of Europe Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.3.12.4. Rest of Europe Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.4. Asia Pacific
8.4.1. Asia Pacific Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.4.2. Asia Pacific Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.4.3. Asia Pacific Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.4.4. Asia Pacific Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.4.5. China
8.4.5.1. China Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.4.5.2. China Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.4.5.3. China Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.4.5.4. China Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.4.6. India
8.4.6.1. India Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.4.6.2. India Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.4.6.3. India Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.4.6.4. India Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.4.7. Japan
8.4.7.1. Japan Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.4.7.2. Japan Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.4.7.3. Japan Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.4.7.4. Japan Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.4.8. South Korea
8.4.8.1. South Korea Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.4.8.2. South Korea Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.4.8.3. South Korea Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.4.8.4. South Korea Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.4.9. Rest of APAC
8.4.9.1. Rest of APAC Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.4.9.2. Rest of APAC Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.4.9.3. Rest of APAC Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.4.9.4. Rest of APAC Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.5. Latin America
8.5.1. Latin America Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.5.2. Latin America Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.5.3. Latin America Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.5.4. Latin America Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.5.5. Brazil
8.5.5.1. Brazil Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.5.5.2. Brazil Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.5.5.3. Brazil Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.5.5.4. Brazil Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.5.6. Rest of LATAM
8.5.6.1. Rest of LATAM Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.5.6.2. Rest of LATAM Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.5.6.3. Rest of LATAM Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.5.6.4. Rest of LATAM Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.6. Middle East and Africa
8.6.1. Middle East and Africa Carbon Nanotubes market estimates and forecast, 2019-2030, (USD Million)
8.6.2. Middle East and Africa Carbon Nanotubes market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.6.3. Middle East and Africa Carbon Nanotubes market estimates and forecast By Technology, 2019-2030, (USD Million)
8.6.4. Middle East and Africa Carbon Nanotubes market estimates and forecast By Application, 2019-2030, (USD Million)
8.6.5. Saudi Arabia
8.6.5.1. Saudi Arabia Carbon Nanotubes market estimates and forecast, 2019-2030, (USD Million)
8.6.5.2. Saudi Arabia Carbon Nanotubes market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.6.5.3. Saudi Arabia Carbon Nanotubes market estimates and forecast By Technology, 2019-2030, (USD Million)
8.6.5.4. Saudi Arabia Carbon Nanotubes market estimates and forecast By Application, 2019-2030, (USD Million)
8.6.6. UAE
8.6.6.1. UAE Carbon Nanotubes market estimates and forecast, 2019-2030, (USD Million)
8.6.6.2. UAE Carbon Nanotubes market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.6.6.3. UAE Carbon Nanotubes market estimates and forecast By Technology, 2019-2030, (USD Million)
8.6.6.4. UAE Carbon Nanotubes market estimates and forecast By Application, 2019-2030, (USD Million)
8.6.7. South Africa
8.6.7.1. South Africa Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.6.7.2. South Africa Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.6.7.3. South Africa Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.6.7.4. South Africa Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.6.8. Israel
8.6.8.1. Israel Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.6.8.2. Israel Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.6.8.3. Israel Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.6.8.4. Israel Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
8.6.9. Rest of MEA
8.6.9.1. Rest of MEA Carbon Nanotubes Market estimates and forecast, 2019-2030, (USD Million)
8.6.9.2. Rest of MEA Carbon Nanotubes Market estimates and forecast By Product Type, 2019-2030, (USD Million)
8.6.9.3. Rest of MEA Carbon Nanotubes Market estimates and forecast By Technology, 2019-2030, (USD Million)
8.6.9.4. Rest of MEA Carbon Nanotubes Market estimates and forecast By Application, 2019-2030, (USD Million)
Chapter 9. Competitive Landscape
9.1. Market Revenue Share by Manufacturers
9.2. Manufacturing Cost Breakdown Analysis
9.3. Mergers & Acquisitions
9.4. Market positioning
9.5. Strategy Benchmarking
9.6. Vendor Landscape
Chapter 10. Company Profiles
10.1. Arkema
10.1.1. Company Overview
10.1.2. Financial Performance
10.1.3. Technology Insights
10.1.4. Strategic Initiatives
10.2. Carbon Solutions, Inc.
10.2.1. Company Overview
10.2.2. Financial Performance
10.2.3. Technology Insights
10.2.4. Strategic Initiatives
10.3. Showa Denko KK
10.3.1. Company Overview
10.3.2. Financial Performance
10.3.3. Technology Insights
10.3.4. Strategic Initiatives
10.4. Nanocyl SA
10.4.1. Company Overview
10.4.2. Financial Performance
10.4.3. Technology Insights
10.4.4. Strategic Initiatives
10.5. Nanoshell LLC
10.5.1. Company Overview
10.5.2. Financial Performance
10.5.3. Technology Insights
10.5.4. Strategic Initiatives
10.6. Hyperion Catalysis International
10.6.1. Company Overview
10.6.2. Financial Performance
10.6.3. Technology Insights
10.6.4. Strategic Initiatives
10.7. Klean Industries Inc.
10.7.1. Company Overview
10.7.2. Financial Performance
10.7.3. Technology Insights
10.7.4. Strategic Initiatives
10.8. Continental Carbon
10.8.1. Company Overview
10.8.2. Financial Performance
10.8.3. Technology Insights
10.8.4. Strategic Initiatives
10.9. CHASM Advanced Materials
10.9.1. Company Overview
10.9.2. Financial Performance
10.9.3. Technology Insights
10.9.4. Strategic Initiatives
10.10. Nano-C, Inc.
10.10.1. Company Overview
10.10.2. Financial Performance
10.10.3. Technology Insights
10.10.4. Strategic Initiatives
10.11. NoPo Nanotechnologies
10.11.1. Company Overview
10.11.2. Financial Performance
10.11.3. Technology Insights
10.11.4. Strategic Initiatives
10.12. Nantero.com
10.12.1. Company Overview
10.12.2. Financial Performance
10.12.3. Technology Insights
10.12.4. Strategic Initiatives
Companies Mentioned
- Arkema
- Carbon Solutions Inc.
- Showa Denko KK
- Nanocyl SA
- Nanoshell LLC
- Hyperion Catalysis International
- Klean Industries Inc.
- Continental Carbon
- CHASM Advanced Materials
- Nano-C Inc.
- NoPo Nanotechnologies
- Nantero.com
