Composite Materials for Automotive

Composite Materials for Automotive Market Outlook

The global composite materials market for the automotive sector is anticipated to reach approximately USD 34.89 billion by 2035, expanding at a compound annual growth rate (CAGR) of around 7.4% from 2025 to 2035. This growth is primarily driven by the increasing demand for lightweight vehicles that enhance fuel efficiency and reduce carbon emissions. The shift toward electric vehicles also propels the need for innovative materials that can optimize battery performance while providing structural integrity. Furthermore, stringent regulations concerning vehicle emissions and safety standards are fostering the adoption of advanced composite materials, as they offer superior strength-to-weight ratios compared to traditional materials. The growing trend of automation and smart manufacturing in the automotive industry further supports the expansion of the composite materials market, making it a vibrant field for investment and innovation.

Growth Factor of the Market

Several key factors contribute to the growth of the composite materials market within the automotive industry. First, the automotive market is increasingly leaning toward sustainability, focusing on reducing the environmental impact of vehicles throughout their life cycles. This has led manufacturers to explore lightweight composite materials that not only enhance performance but also minimize carbon footprints. Second, technological advancements in manufacturing processes, such as automated fiber placement and 3D printing, have made it easier and more cost-effective to produce complex composite components. Third, the rise of electric vehicles (EVs) has created a unique demand for lightweight materials that improve overall efficiency and extend battery life. Additionally, the automotive sector is investing heavily in research and development to create stronger, more durable composites, thus driving market growth. Lastly, the increasing use of composites in high-performance racing vehicles also sets a benchmark that encourages broader adoption across mainstream automobile production.

Key Highlights of the Market

• The global composite materials market in the automotive sector is projected to grow at a CAGR of 7.4% from 2025 to 2035.
• Lightweight composites significantly improve fuel efficiency and reduce emissions in vehicles.
• Technological advancements in composite manufacturing processes are enhancing production efficiency.
• The rising adoption of electric and hybrid vehicles is fueling demand for advanced composite materials.
• Sustainability in automotive production is becoming a priority, pushing manufacturers to adopt eco-friendly composite solutions.

By Product Type

Polymer Matrix Composites:

Polymer matrix composites (PMCs) are widely utilized in the automotive industry due to their excellent mechanical properties, lightweight nature, and resistance to corrosion. These composites primarily consist of polymers like epoxy, polyester, or vinyl ester reinforced with fibers such as glass or carbon. The automotive sector favors PMCs for applications in structural parts, interior components, and even body panels, where weight reduction is crucial for enhancing performance and efficiency. Innovations in polymer formulations and reinforcement techniques have further improved their impact resistance and durability, thus solidifying their position as a preferred choice in automotive manufacturing. The increasing trend toward electric vehicles is also stimulating demand for PMCs, as manufacturers seek materials that can contribute to energy efficiency.

Metal Matrix Composites:

Metal matrix composites (MMCs) are materials that combine metals with other substances to create a composite material with enhanced properties. In the automotive sector, MMCs are employed for components such as engine blocks, transmission cases, and brake systems. These composites provide superior strength, thermal conductivity, and wear resistance compared to conventional metals. The growing need for high-performance automotive components that can withstand extreme conditions is driving the adoption of MMCs, particularly in performance and luxury vehicles. As manufacturers focus on optimizing engine performance and enhancing durability, MMCs are anticipated to see significant growth in the coming years.

Ceramic Matrix Composites:

Ceramic matrix composites (CMCs) are gaining traction in the automotive industry due to their exceptional thermal resistance, lightweight nature, and high strength at elevated temperatures. Although traditionally used in aerospace applications, there is a growing interest in CMCs for automotive applications, particularly in high-performance and racing vehicles. As automotive manufacturers aim to enhance engine efficiency and reduce heat loss, CMCs offer a promising solution due to their ability to withstand high operating temperatures without degrading. Furthermore, advancements in manufacturing techniques for CMCs are expected to reduce production costs, making them more accessible for widespread use in the automotive market.

Hybrid Composites:

Hybrid composites, which combine different types of fibers or matrix materials, are increasingly being used in the automotive sector to leverage the advantages of each constituent material. These composites provide a balance of properties such as strength, weight, and cost-effectiveness, making them suitable for varied automotive applications. The versatility of hybrid composites allows manufacturers to tailor materials specifically for certain vehicle components, thereby enhancing performance and durability. As demand for customized solutions grows, hybrid composites are poised to gain a stronger foothold in the automotive market.

Natural Fiber Composites:

Natural fiber composites (NFCs) are becoming popular in the automotive industry as a sustainable alternative to traditional composites. These materials are made from renewable resources, such as hemp, jute, or flax, combined with bio-based resins, offering reduced environmental impact without compromising mechanical performance. The increasing consumer demand for eco-friendly products is encouraging automakers to incorporate NFCs into non-structural applications such as interior panels, dashboards, and door trims. Additionally, NFCs can provide weight savings while enhancing the overall aesthetic appeal of vehicles, thus supporting the automotive sector's shift toward sustainability.

By Application

Automotive:

In the automotive industry, the application of composite materials is paramount, as they contribute significantly to vehicle performance and efficiency. Composites are utilized in various parts, including body panels, chassis, and interior components, where weight reduction is essential for enhancing fuel economy. The increasing regulation on emissions and the push for electric vehicles have further accelerated the adoption of composites in automotive manufacturing. With automotive manufacturers continuously seeking innovative materials that provide strength and durability while being lightweight, the demand for composite materials in this sector is expected to grow substantially over the forecast period.

Aerospace & Defense:

The aerospace and defense sectors heavily rely on composite materials due to their high strength-to-weight ratios and excellent fatigue resistance. These materials are primarily used in aircraft structures, components, and military vehicles, where performance and safety are non-negotiable. The increasing need for fuel-efficient aircraft and advancements in missile technologies are encouraging the adoption of composites in these sectors. Additionally, ongoing research and development efforts aimed at improving the properties and manufacturability of aerospace composites contribute to the sector's growth, leading to a broader application scope.

Construction:

Composite materials are utilized in the construction industry for various applications, including structural reinforcement, facades, and flooring systems. Their durability, resistance to environmental degradation, and lightweight nature make them an attractive choice for modern construction projects. The growing emphasis on sustainable building practices is also driving the demand for composite materials, as they can help reduce the overall carbon footprint of buildings. As the construction industry moves toward innovative solutions for energy efficiency and enhanced performance, the use of composites is expected to expand.

Wind Energy:

As the world shifts toward renewable energy sources, composite materials are gaining popularity in the wind energy sector. These materials are primarily used in the manufacturing of wind turbine blades, which require high strength and lightweight characteristics to optimize performance. The growing investment in wind energy projects globally is expected to propel the demand for composite materials, with manufacturers focusing on improving the efficiency and lifespan of turbine blades. As technology advances, innovations in composite materials for wind energy applications are likely to continue evolving, making them key players in the renewable energy landscape.

Others:

Other applications of composite materials span various industries, including sports equipment, marine, and consumer goods. In the sports sector, composites enhance the performance of equipment like bicycles, skis, and surfboards by providing lightweight and durable solutions. In the marine industry, composite materials are used in boat hulls and components, offering resistance to corrosion and reducing weight. The versatility of composites enables their adoption across numerous applications, ensuring that they remain integral to various sectors beyond automotive, aerospace, and construction.

By Manufacturing Process

Lay-Up:

The lay-up process is one of the most widely used techniques for manufacturing composite materials, particularly in the automotive industry. This method involves layering sheets of reinforcement material, such as fiberglass or carbon fiber, with a resin binder to form the desired shape. The lay-up process is favored for its versatility, allowing manufacturers to create complex geometries and customize properties according to specific requirements. As the demand for lightweight and strong components grows, the lay-up process continues to be a primary manufacturing technique, particularly for large parts where precision and quality are paramount.

Filament Winding:

Filament winding is a manufacturing process utilized primarily for creating cylindrical or spherical composite structures. This process involves winding continuous fibers around a rotating mandrel and saturating them with resin, resulting in a high-strength, lightweight product. In the automotive sector, filament winding is commonly used for producing fuel tanks, pressure vessels, and other components that require high structural integrity. The ability to control the orientation of the fibers during the winding process allows for the optimization of mechanical properties, making it an attractive option for manufacturers seeking performance-enhancing materials.

Injection Molding:

Injection molding is a popular manufacturing process in the automotive sector, particularly for producing complex composite components with high precision and repeatability. In this process, composite materials are heated until they become pliable and then injected into a mold to form the desired shape. Injection molding is particularly advantageous for high-volume production, as it allows for rapid cycle times and consistent quality. With the ongoing advancements in material formulations and injection molding technology, manufacturers are increasingly integrating this process for creating intricate automotive components that meet stringent performance standards.

Compression Molding:

Compression molding is a manufacturing technique widely utilized in the automotive industry for producing composite parts with complex shapes. The process involves placing a pre-measured amount of composite material into a heated mold, where it is subjected to heat and pressure until it takes on the desired shape. This method is favored for its efficiency in producing large quantities of parts while maintaining consistent quality and performance. As the automotive industry continues to prioritize lightweight and rugged materials, compression molding remains a key process for transforming raw composites into high-performance components.

Resin Transfer Molding:

Resin transfer molding (RTM) is an advanced manufacturing process used to create high-quality composite parts for the automotive sector. In this technique, dry reinforcement materials are placed in a mold, and resin is injected under pressure to saturate the fibers. RTM offers several advantages, including the ability to produce complex shapes with excellent surface finishes and uniform mechanical properties. The growing demand for lightweight and durable components in the automotive industry is driving the adoption of RTM, as it allows for the efficient production of components that meet rigorous performance requirements.

By Fiber Type

Carbon Fiber Composites:

Carbon fiber composites are renowned for their exceptional strength-to-weight ratios and are increasingly being utilized in the automotive industry for high-performance applications. These composites exhibit superior stiffness and tensile strength, making them ideal for components that require high durability, such as chassis, body panels, and structural reinforcements. The rising demand for luxury and sports vehicles that emphasize performance and efficiency is driving the adoption of carbon fiber composites. While the initial costs may be higher compared to other materials, the long-term benefits of enhanced performance and reduced weight justify the investment.

Glass Fiber Composites:

Glass fiber composites are widely used in the automotive sector due to their cost-effectiveness and satisfactory mechanical properties. These composites provide decent tensile strength and impact resistance, making them suitable for non-structural components such as interior panels, dashboards, and body shells. The versatility of glass fiber composites allows for various applications, making them a popular choice for automotive manufacturers seeking a balance between performance and cost. Continuous advancements in glass fiber technology are also enhancing the properties of these composites, further solidifying their place in the automotive market.

Aramid Fiber Composites:

Aramid fiber composites, known for their exceptional strength and impact resistance, are increasingly being utilized in the automotive industry. These composites are particularly valued for their performance in high-stress applications, including protective components and performance racing vehicles. The unique properties of aramid fibers, such as their lightweight nature and resistance to abrasion, make them ideal for automotive applications where safety and durability are paramount. As the automotive sector continues to prioritize performance and safety, the demand for aramid fiber composites is expected to rise.

Natural Fiber Composites:

Natural fiber composites made from renewable resources are gaining popularity in the automotive sector as a sustainable alternative to synthetic materials. These composites are composed of natural fibers like hemp, jute, or flax, combined with bio-based resins that provide mechanical strength while reducing environmental impact. The growing consumer awareness of sustainability and eco-friendly materials is driving the adoption of natural fiber composites in various automotive applications, particularly in non-structural components. Furthermore, advancements in processing techniques are enhancing the performance and durability of natural fiber composites, making them a viable option for the automotive industry.

Others:

Other fiber types in the composite materials market include hybrid fibers and specialty fibers such as basalt and PBO (polybenzoxazole). Hybrid composites combine different fibers to optimize performance characteristics based on specific application requirements, providing manufacturers with enhanced versatility. Specialty fibers, like basalt, offer advantages such as thermal resistance and excellent mechanical properties, making them suitable for niche applications in the automotive industry. As the demand for high-performance materials continues to grow, manufacturers are exploring various fiber types, ensuring a diverse range of options for automotive applications.

By Region

The regional analysis of the composite materials market within the automotive sector indicates varying growth trends and opportunities across different geographies. North America holds a significant share of the market, driven by strong automotive production capabilities and a robust demand for advanced materials in the automotive industry. The U.S. accounted for approximately 40% of the North American market, supported by an increasing focus on lightweight materials and the development of electric vehicles. The region is projected to exhibit a CAGR of around 6.5% over the forecast period, reflecting the rise in automotive innovations and sustainable manufacturing practices.

Europe is another crucial region for the composite materials market, with countries like Germany, France, and the UK leading the charge. The European automotive industry is undergoing a transformation towards electric vehicles, which has significantly increased the demand for lightweight and high-performance composite materials. The European market is anticipated to expand at a CAGR of approximately 7.2% from 2025 to 2035, driven by stringent regulations related to emissions and safety standards. In contrast, the Asia Pacific region is expected to witness the highest growth rate, fueled by rapid industrialization, increasing vehicle production, and an expanding automotive customer base. The demand for composite materials in the automotive sector is particularly surging in China and India, with projections indicating a CAGR of about 8.5% within the region.

Opportunities

One of the most significant opportunities in the composite materials market for the automotive sector lies in the transition toward electric and hybrid vehicles. As manufacturers strive to enhance the performance and efficiency of these vehicles, the demand for lightweight materials will continue to grow. Composites, known for their excellent strength-to-weight ratios, are exceptionally well-suited for this purpose, making them integral to the design and production of electric vehicles. The increasing emphasis on sustainability and eco-friendliness also opens new avenues for the development of natural fiber composites, which can help automakers meet consumer expectations and regulatory requirements. This shift toward sustainable materials is likely to foster innovation and collaboration within the industry, leading to the creation of new composite solutions tailored for the automotive market.

Another notable opportunity exists in the advancements in manufacturing technologies for composite materials. Techniques such as automated fiber placement (AFP) and 3D printing are revolutionizing the way composites are produced, allowing for greater precision, reduced waste, and increased efficiency. The adoption of these advanced manufacturing methods can lead to significant cost savings for automotive manufacturers, enabling them to incorporate composites into a wider range of applications. Additionally, ongoing research and development efforts aimed at enhancing the properties of composite materials will contribute to their growing popularity in the automotive sector, as manufacturers seek to improve performance and reduce production costs.

Threats

Despite the numerous opportunities within the composite materials market for the automotive sector, there are several threats that could impede growth. One significant challenge is the high initial cost associated with the production and processing of composite materials. While these materials offer long-term benefits such as weight reduction and enhanced performance, the upfront investment can be a deterrent for many automotive manufacturers, particularly those operating on tight budgets or profit margins. Additionally, fluctuating raw material prices can impact the overall cost of composite production, leading to unpredictable pricing for end products. As the automotive industry continues to navigate these economic pressures, manufacturers must find ways to balance cost and performance to remain competitive in the market.

Another potential threat stems from the challenges associated with recycling and waste management of composite materials at the end of their life cycle. Unlike traditional materials such as metals and plastics, composites can be difficult to recycle, raising concerns over environmental sustainability. As consumer awareness and regulatory scrutiny of sustainability practices increase, automotive manufacturers may face pressure to develop viable recycling solutions for composite materials. Failure to address these concerns could damage the reputation of composite materials and hinder their acceptance within the automotive sector, ultimately limiting market growth.

Competitor Outlook

• Toray Industries, Inc.
• Hexcel Corporation
• Teijin Limited
• Owens Corning
• Solvay S.A.
• Mitsubishi Chemical Holdings Corporation
• Genera, Inc.
• BASF SE
• 3M Company
• SABIC
• DuPont de Nemours, Inc.
• Royal DSM N.V.
• Lanxess AG
• Covestro AG
• Huntsman Corporation

The competitive landscape of the composite materials market in the automotive sector is characterized by the presence of several key players who are continuously striving to innovate and provide advanced solutions. Companies such as Toray Industries, Hexcel Corporation, and Teijin Limited are leading the way with their extensive portfolios of high-performance composite materials tailored for automotive applications. These companies are investing heavily in research and development to enhance the properties of their composites, ensuring that they meet the evolving requirements of the automotive industry. Additionally, strategic partnerships and collaborations among manufacturers and technology firms are becoming increasingly common as companies seek to leverage expertise and share resources to accelerate innovation.

Moreover, the competition in the composite materials market is intensifying as more players enter the field, driven by the growing demand for lightweight and sustainable automotive solutions. As a result, companies are focusing on differentiation through unique product offerings and specialized applications. For instance, Owens Corning and Solvay S.A. are actively developing eco-friendly composite materials made from natural fibers, responding to the increasing consumer preference for sustainable options. Additionally, major chemical manufacturers such as BASF and DuPont de Nemours are expanding their product lines to include advanced composites that cater to the specific needs of automotive manufacturers, demonstrating their commitment to this lucrative market segment.

In conclusion, the competitive landscape of the composite materials market for the automotive sector is dynamic, with numerous players vying for market share. Companies are leveraging technological advancements, sustainable practices, and innovative manufacturing processes to position themselves for future growth. As the automotive industry continues to evolve, it is crucial for manufacturers to adapt to changing demands and invest in the development of advanced composite materials that align with market trends. Key players such as Mitsubishi Chemical Holdings Corporation and Genera, Inc. are likely to be at the forefront of this evolution as they explore new opportunities in the ever-changing automotive landscape.

• 1 Appendix

  • 1.1 List of Tables
  • 1.2 List of Figures

• 2 Introduction

  • 2.1 Market Definition
  • 2.2 Scope of the Report
  • 2.3 Study Assumptions
  • 2.4 Base Currency & Forecast Periods

• 3 Market Dynamics

  • 3.1 Market Growth Factors
  • 3.2 Economic & Global Events
  • 3.3 Innovation Trends
  • 3.4 Supply Chain Analysis

• 4 Consumer Behavior

  • 4.1 Market Trends
  • 4.2 Pricing Analysis
  • 4.3 Buyer Insights

• 5 Key Player Profiles

  • 5.1 SABIC
    • 5.1.1 Business Overview
    • 5.1.2 Products & Services
    • 5.1.3 Financials
    • 5.1.4 Recent Developments
    • 5.1.5 SWOT Analysis
  • 5.2 BASF SE
    • 5.2.1 Business Overview
    • 5.2.2 Products & Services
    • 5.2.3 Financials
    • 5.2.4 Recent Developments
    • 5.2.5 SWOT Analysis
  • 5.3 3M Company
    • 5.3.1 Business Overview
    • 5.3.2 Products & Services
    • 5.3.3 Financials
    • 5.3.4 Recent Developments
    • 5.3.5 SWOT Analysis
  • 5.4 Lanxess AG
    • 5.4.1 Business Overview
    • 5.4.2 Products & Services
    • 5.4.3 Financials
    • 5.4.4 Recent Developments
    • 5.4.5 SWOT Analysis
  • 5.5 Covestro AG
    • 5.5.1 Business Overview
    • 5.5.2 Products & Services
    • 5.5.3 Financials
    • 5.5.4 Recent Developments
    • 5.5.5 SWOT Analysis
  • 5.6 Solvay S.A.
    • 5.6.1 Business Overview
    • 5.6.2 Products & Services
    • 5.6.3 Financials
    • 5.6.4 Recent Developments
    • 5.6.5 SWOT Analysis
  • 5.7 Genera, Inc.
    • 5.7.1 Business Overview
    • 5.7.2 Products & Services
    • 5.7.3 Financials
    • 5.7.4 Recent Developments
    • 5.7.5 SWOT Analysis
  • 5.8 Owens Corning
    • 5.8.1 Business Overview
    • 5.8.2 Products & Services
    • 5.8.3 Financials
    • 5.8.4 Recent Developments
    • 5.8.5 SWOT Analysis
  • 5.9 Royal DSM N.V.
    • 5.9.1 Business Overview
    • 5.9.2 Products & Services
    • 5.9.3 Financials
    • 5.9.4 Recent Developments
    • 5.9.5 SWOT Analysis
  • 5.10 Teijin Limited
    • 5.10.1 Business Overview
    • 5.10.2 Products & Services
    • 5.10.3 Financials
    • 5.10.4 Recent Developments
    • 5.10.5 SWOT Analysis
  • 5.11 Hexcel Corporation
    • 5.11.1 Business Overview
    • 5.11.2 Products & Services
    • 5.11.3 Financials
    • 5.11.4 Recent Developments
    • 5.11.5 SWOT Analysis
  • 5.12 Huntsman Corporation
    • 5.12.1 Business Overview
    • 5.12.2 Products & Services
    • 5.12.3 Financials
    • 5.12.4 Recent Developments
    • 5.12.5 SWOT Analysis
  • 5.13 Toray Industries, Inc.
    • 5.13.1 Business Overview
    • 5.13.2 Products & Services
    • 5.13.3 Financials
    • 5.13.4 Recent Developments
    • 5.13.5 SWOT Analysis
  • 5.14 DuPont de Nemours, Inc.
    • 5.14.1 Business Overview
    • 5.14.2 Products & Services
    • 5.14.3 Financials
    • 5.14.4 Recent Developments
    • 5.14.5 SWOT Analysis
  • 5.15 Mitsubishi Chemical Holdings Corporation
    • 5.15.1 Business Overview
    • 5.15.2 Products & Services
    • 5.15.3 Financials
    • 5.15.4 Recent Developments
    • 5.15.5 SWOT Analysis

• 6 Market Segmentation

  • 6.1 Composite Materials for Automotive Market, By Fiber Type
    • 6.1.1 Carbon Fiber Composites
    • 6.1.2 Glass Fiber Composites
    • 6.1.3 Aramid Fiber Composites
    • 6.1.4 Natural Fiber Composites
    • 6.1.5 Others
  • 6.2 Composite Materials for Automotive Market, By Application
    • 6.2.1 Automotive
    • 6.2.2 Aerospace & Defense
    • 6.2.3 Construction
    • 6.2.4 Wind Energy
    • 6.2.5 Others
  • 6.3 Composite Materials for Automotive Market, By Product Type
    • 6.3.1 Polymer Matrix Composites
    • 6.3.2 Metal Matrix Composites
    • 6.3.3 Ceramic Matrix Composites
    • 6.3.4 Hybrid Composites
    • 6.3.5 Natural Fiber Composites
  • 6.4 Composite Materials for Automotive Market, By Manufacturing Process
    • 6.4.1 Lay-Up
    • 6.4.2 Filament Winding
    • 6.4.3 Injection Molding
    • 6.4.4 Compression Molding
    • 6.4.5 Resin Transfer Molding

• 7 Competitive Analysis

  • 7.1 Key Player Comparison
  • 7.2 Market Share Analysis
  • 7.3 Investment Trends
  • 7.4 SWOT Analysis

• 8 Research Methodology

  • 8.1 Analysis Design
  • 8.2 Research Phases
  • 8.3 Study Timeline

• 9 Future Market Outlook

  • 9.1 Growth Forecast
  • 9.2 Market Evolution

• 10 Geographical Overview

  • 10.1 Europe - Market Analysis
    • 10.1.1 By Country
      • 10.1.1.1 UK
      • 10.1.1.2 France
      • 10.1.1.3 Germany
      • 10.1.1.4 Spain
      • 10.1.1.5 Italy
  • 10.2 Asia Pacific - Market Analysis
    • 10.2.1 By Country
      • 10.2.1.1 India
      • 10.2.1.2 China
      • 10.2.1.3 Japan
      • 10.2.1.4 South Korea
  • 10.3 Latin America - Market Analysis
    • 10.3.1 By Country
      • 10.3.1.1 Brazil
      • 10.3.1.2 Argentina
      • 10.3.1.3 Mexico
  • 10.4 North America - Market Analysis
    • 10.4.1 By Country
      • 10.4.1.1 USA
      • 10.4.1.2 Canada
  • 10.5 Middle East & Africa - Market Analysis
    • 10.5.1 By Country
      • 10.5.1.1 Middle East
      • 10.5.1.2 Africa
  • 10.6 Composite Materials for Automotive Market by Region

• 11 Global Economic Factors

  • 11.1 Inflation Impact
  • 11.2 Trade Policies

• 12 Technology & Innovation

  • 12.1 Emerging Technologies
  • 12.2 AI & Digital Trends
  • 12.3 Patent Research

• 13 Investment & Market Growth

  • 13.1 Funding Trends
  • 13.2 Future Market Projections

• 14 Market Overview & Key Insights

  • 14.1 Executive Summary
  • 14.2 Key Trends
  • 14.3 Market Challenges
  • 14.4 Regulatory Landscape

Segments Analyzed in the Report

The global Composite Materials for Automotive market is categorized based on

By Product Type

• Polymer Matrix Composites
• Metal Matrix Composites
• Ceramic Matrix Composites
• Hybrid Composites
• Natural Fiber Composites

By Application

• Automotive
• Aerospace & Defense
• Construction
• Wind Energy
• Others

By Manufacturing Process

• Lay-Up
• Filament Winding
• Injection Molding
• Compression Molding
• Resin Transfer Molding

By Fiber Type

• Carbon Fiber Composites
• Glass Fiber Composites
• Aramid Fiber Composites
• Natural Fiber Composites
• Others

By Region

• North America
• Europe
• Asia Pacific
• Latin America
• Middle East & Africa

Key Players

• Toray Industries, Inc.
• Hexcel Corporation
• Teijin Limited
• Owens Corning
• Solvay S.A.
• Mitsubishi Chemical Holdings Corporation
• Genera, Inc.
• BASF SE
• 3M Company
• SABIC
• DuPont de Nemours, Inc.
• Royal DSM N.V.
• Lanxess AG
• Covestro AG
• Huntsman Corporation