全球航太碳纤维复合材料中间体市场按产品类型、结构、基质类型、应用和最终用途划分 - 机会分析和产业预测，2024-2033 年

全球航太碳纤维复合材料中间体市场预计在 2023 年达到 146 亿美元，到 2033 年将达到 500 亿美元，2024 年至 2033 年的复合年增长率为 13.3%。

中级航太市场的碳纤维复合材料是指将碳纤维与环氧树脂或热塑性塑胶等聚合物基质结合製成的材料。这些复合材料具有出色的强度重量比、刚性和耐用性，使其成为航太应用的理想选择。利用其重量轻和高性能的特点，它被用于各种飞机部件，包括机翼、机身和内部组件。

提高燃油效率和减少温室气体排放的需求推动了航太工业对轻质材料的需求，这也是碳纤维复合材料的主要驱动力。这些复合材料取代了较重的金属，这大大节省了燃料并降低了营运成本。此外，受航空需求和国防预算成长的推动，民航机和军用飞机产量不断增加，进一步推动了市场的发展。自动纤维铺放 (AFP)、树脂转注成形(RTM) 和 3D 列印等技术进步正在提高製造效率并降低成本，使碳纤维复合材料在航太应用方面更具吸引力。这些因素共同推动了碳纤维复合材料在航太领域的应用扩展。

碳纤维复合材料由于其出色的强度重量比和耐用性而成为现代飞机必不可少的材料。碳纤维复合材料用于机翼、机身段和尾部结构等关键部件，大大减轻了飞机的整体重量并提高了燃油效率。此外，这些复合材料也用于引擎零件、内装件和起落架舱门，有助于提高性能并降低营运成本。碳纤维复合材料的多功能性使其成为民航机和军用飞机的必备材料，有助于推动产业朝向更有效率、高性能的航空解决方案迈进。

然而，航太市场碳纤维复合材料中间体的成长受到多种因素的限制。由于原料昂贵、製程能耗高以及需要专业劳动力和设备，导致生产成本高，使得广泛采用这些复合材料在财务上面临挑战。此外，需要精密和先进工程技术的复杂製造流程进一步增加了成本和生产时间。以更低的成本或更简单的製造流程提供同等性能的替代材料（如铝锂合金和其他先进材料）的可用性也带来了重大挑战。总的来说，这些经济和技术障碍阻碍了碳纤维复合材料在航太工业的广泛应用。

碳纤维复合材料技术的最新进展集中于提高材料强度、耐用性和永续性。一项值得注意的技术创新是麻省理工学院工程师开发的「奈米缝合」。此技术将奈米碳管微观森林嵌入复合材料层间，显着提高抗裂性能，最高可达 60%。这项进步消除了复合材料的主要弱点，使其在航太应用中更加坚固和可靠。

另一项突破是开发出闭合迴路製程。此方法由美国能源部橡树岭国家实验室发明，可完全回收起始材料，促进永续性并减少废弃物。

此外，碳纤维回收利用的创新技术也不断出现，例如利用回收的碳纤维製造半成品长纤维产品。这种方法不仅支援环境永续性，而且还为各种应用提供高性能材料。总的来说，这些进步提高了碳纤维复合材料的性能、耐用性和环境影响，使其对各行各业，尤其是航太更具吸引力。预计这些发展将为预测期内航太领域碳纤维复合材料中间体市场的发展提供充足的机会。

航太碳纤维复合材料中间体市场根据产品类型、基质类型、结构、应用、最终用途和地区进行细分。依产品类型，市场分为预浸料、颗粒、模製品、织物、拉挤型材等。根据基质类型，市场分为聚合物基质、碳基质、陶瓷基质和其他。根据结构，市场分为初级市场、次级市场和内部市场。依用途分为民航机、军用飞机、太空船、无人机、直升机、通用航空等。根据最终用途，市场分为目的地设备製造商以及维护、维修和大修提供者。根据地区，对北美、欧洲、亚太地区、拉丁美洲、中东和非洲的航太碳纤维复合复合材料中间体市场进行分析。

预浸料在市场规模方面占据主导地位，因为它们广泛应用于高性能航太零件，尤其是飞机的主要结构。由于其具有优异的强度重量比和易于在自动化过程中使用等特性，因此它受到航太航太製造商的青睐。然而，由于颗粒在射出成型製程的应用越来越广泛，因此其成长速度最快。射出成型製程在航太工业中越来越受欢迎，因为它可以生产出形状复杂、精度高、成本低的产品。

主要结构部分占据市场主导地位，因为机翼和机身等关键飞机部件需要坚固而轻质的材料。这些应用对碳纤维复合材料的需求很高，这是由于飞机变得更轻、更省油的需求。此外，随着製造商寻求使用更轻的复合材料替代非关键金属部件来进一步减轻飞机重量并提高效率，二级结构部分正在快速增长。

碳基体材料由于其优异的高温性能而占据主导地位并迅速增长，这使得它们对于耐热性至关重要的航太应用至关重要，例如引擎零件和隔热。

民航机是一个主要的应用领域，其驱动力来自于航空旅行的持续成长以及对新型、更省油的飞机的需求。在民航机中采用碳纤维复合材料对于降低营运成本和遵守环境法规至关重要。此外，由于太空探勘和卫星发射的激增，太空船领域是成长最快的领域。对轻量耐用材料的需求对于降低发射成本和延长任务寿命至关重要。

目标商标产品製造商（OEM）占据市场主导地位，因为他们是飞机和太空船的主要生产商，需要大量碳纤维复合材料来生产新飞机。此外，随着现有飞机老化并需要更频繁的维修和升级，维护、修理和大修 (MRO) 提供者也蓬勃发展。碳纤维复合材料由于其优异的性能特点，在修復应用中越来越受欢迎。

北美占据主导地位，因为波音和洛克希德马丁等主要航太製造商的存在，以及他们对先进材料和技术的关注。然而，由于航太基础设施投资的增加和新兴市场对先进材料的采用，拉丁美洲、中东和非洲 ( LAMEA ) 地区预计将增长最快。

东丽已成为航太领域的主要企业，这主要归功于其先进的碳纤维复合材料。东丽是全球最大的碳纤维製造商，占有全球约35%的市场份额，其材料广泛应用于波音787梦幻飞机等飞机，为大幅减轻重量和提高燃油效率做出了贡献。

东丽也参与了美国未来远程突击飞机 (FLRAA) 计划等创新计划。东丽的碳纤维生产线支持该新一代飞机轻量、高强度机身的生产。此外，东丽正在利用材料资讯学开发具有优异阻燃性和机械性能的碳纤维增强塑胶 (CFRP)，以进一步增强航太应用。

相关人员的主要利益

• 本研究报告定量提供了 2023 年至 2033 年航太用碳纤维复合材料中间体的市场细分、当前趋势、估计和趋势分析，并确定了航太航太用碳纤维复合材料中间体的突出市场机会。
• 它为市场研究提供与市场驱动因素、市场限制因素和市场机会相关的资讯。
• 波特五力分析强调了买家和供应商的潜力，使相关人员能够做出利润驱动的商业决策并加强供应商-买家网络。
• 对航太领域碳纤维复合材料中间体市场的细分进行详细分析有助于确定市场机会。
• 每个地区的主要国家都根据收益贡献进行划分。
• 市场公司的定位有利于基准化分析，并能清楚了解市场公司的当前地位。
• 本研究报告包括对区域和全球碳纤维复合材料中级航太市场趋势、主要企业、细分市场、应用领域和市场成长策略的分析。

此报告可进行客製化（可能需要支付额外费用和製定时间表）

• 生产能力
• 装置量分析
• 投资机会
• 新参与企业（按地区）
• 科技趋势分析
• 消费者偏好和产品规格
• 主要企业的新产品开发/产品矩阵
• 监管指南
• 策略建议
• 根据客户兴趣客製化的其他公司简介
• 按国家或地区进行的额外分析 - 市场规模和预测
• 平均售价分析/价格点分析
• 交叉細項分析-市场规模与预测
• 扩展公司简介列表
• 历史市场资料
• 导入/汇出分析/资料
• Excel 格式的主要企业详细资料（包括位置、联络资讯、供应商/供应商网路等）
• 客户/消费者/原料供应商名单－价值链分析
• 产品消费分析
• SWOT 分析
• 批量市场规模及预测

目录

第 1 章 简介

第 2 章执行摘要

第三章 市场概况

• 市场定义和范围
• 主要发现
  • 影响因素
  • 主要投资机会
• 波特五力分析
• 市场动态
  • 驱动程式
    • 航太工业对轻量材料的需求不断增加
    • 民用和军用飞机产量成长
  • 限制因素
    • 碳纤维复合材料製造成本高
    • 复杂的製造工艺
  • 机会
    • 新兴市场扩张
• 平均销售价格
• 价值链分析
• 监管指南
• 专利状况

第 4 章航太碳纤维复合材料中间体市场（依产品种类）

• 概述
• 预浸料
• 颗粒
• 模压产品
  • 航太市场中成型碳纤维复合材料中间体的成型类型
• 织物
• 拉挤型材
• 其他的

第 5 章航太碳纤维复合材料中间体市场（依结构）

• 概述
• 基本的
• 次要
• 内部的

第 6 章航太碳纤维复合材料中间体市场（依基质类型）

• 概述
• 聚合物基质
• 碳基质
• 陶瓷基质
• 其他的

第 7 章航太碳纤维复合材料中间体市场（依应用）

• 概述
• 民航机
• 军用机
• 太空船
• 无人驾驶飞行器（UAV）
• 直升机
• 通用航空

第 8 章航太碳纤维复合材料中间体市场（依应用）

• 概述
• 目的地设备製造商（OEM）
• 维修、维修和大修 (MRO) 公司

第 9 章航太碳纤维复合材料中间体市场（按区域）

• 概述
• 北美洲
  • 美国
  • 加拿大
  • 墨西哥
• 欧洲
  • 法国
  • 德国
  • 义大利
  • 西班牙
  • 英国
  • 其他的
• 亚太地区
  • 中国
  • 日本
  • 印度
  • 韩国
  • 澳洲
  • 其他的
• 拉丁美洲、中东和非洲
  • 巴西
  • 南非
  • 沙乌地阿拉伯
  • 其他的

第十章 竞争格局

• 介绍
• 关键成功策略
• 前 10 家公司的产品映射
• 竞争仪錶板
• 竞争热图
• 主要企业定位（2023年）

第十一章 公司简介

• TORAY INDUSTRIES, INC.
• Mitsubishi Chemical Group Corporation.
• Hexcel Corporation
• SGL Carbon
• TEIJIN LIMITED.
• Solvay
• ISOVOLTA AG
• SAERTEX GmbH & Co.KG
• Rock West Composites, Inc.
• Huntsman Corporation

The global carbon fiber composite intermediates in aerospace market was valued at $14.6 billion in 2023, and is projected to reach $50 billion by 2033, growing at a CAGR of 13.3% from 2024 to 2033. Carbon fiber composites in the intermediate aerospace market refer to materials made by combining carbon fibers with a polymer matrix, such as epoxy or thermoplastics. These composites offer exceptional strength-to-weight ratios, rigidity, and durability, making them ideal for aerospace applications. They are used in various aircraft components, including wings, fuselage sections, and interior elements, due to their lightweight and high-performance characteristics.

The aerospace industry's increasing demand for lightweight materials, driven by the need for improved fuel efficiency and reduced greenhouse gas emissions, is a major driver for carbon fiber composites. These composites replace heavier metals, leading to significant fuel savings and lower operational costs. In addition, the growth in commercial and military aircraft production, fueled by rising air travel demand and defense budgets, further boosts the market. Technological advancements, such as automated fiber placement (AFP), resin transfer molding (RTM), and 3D printing, have enhanced manufacturing efficiency and reduced costs, making carbon fiber composites more attractive for aerospace applications. These factors collectively contribute to the expanding utilization of carbon fiber composites in the aerospace sector.

Carbon fiber composites are integral to modern aircraft due to their exceptional strength-to-weight ratio and durability. They are used in critical components such as wings, fuselage sections, and tail structures, significantly reducing the aircraft's overall weight and enhancing fuel efficiency. In addition, these composites are employed in engine components, interior elements, and landing gear doors, contributing to improved performance and operational cost savings. The versatility of carbon fiber composites makes them essential for both commercial and military aircraft, supporting the industry's push toward more efficient and high-performance aviation solutions.

However, the growth of carbon fiber composite intermediates in the aerospace market is restrained by several factors. High production costs, driven by expensive raw materials, energy-intensive processes, and the need for specialized labor and equipment, make these composites financially challenging for widespread adoption. In addition, the complex manufacturing processes, requiring precision and advanced engineering techniques, further increase costs and production timelines. The availability of substitutes, such as aluminum-lithium alloys and other advanced materials, which offer comparable performance at lower costs or with simpler manufacturing processes, also poses a significant challenge. These economic and technical barriers collectively hinder the broader adoption of carbon fiber composites in the aerospace industry.

Recent advancements in carbon fiber composite technology have focused on enhancing material strength, durability, and sustainability. One notable innovation is "nano stitching," developed by MIT engineers. This technique involves embedding microscopic forests of carbon nanotubes between composite layers, significantly improving resistance to cracks by up to 60%. This advancement addresses the primary vulnerability of composite materials, making them more robust and reliable for aerospace applications.

Another breakthrough is the development of a closed-loop process for synthesizing and fully recovering carbon-fiber-reinforced polymers (CFRPs). This method, designed by the Department of Energy's Oak Ridge National Laboratory, allows for the complete recovery of starting materials, promoting sustainability and reducing waste.

In addition, innovations in recycling carbon fiber have emerged, such as the creation of semi-finished, long fiber products from reclaimed carbon fibers. This approach not only supports environmental sustainability but also provides high-performance materials for various applications. These advancements collectively enhance the performance, durability, and environmental impact of carbon fiber composites, making them more attractive for a wide range of industries, especially aerospace. The presence of these developments is expected to provide ample opportunities for the development of the carbon fiber composites intermediates in aerospace market during the forecast period.

The carbon fiber composite intermediates in aerospace market is segmented into product type, matrix type, structure, application, end-use, and region. On the basis of product type, the market is divided into prepreg, pellets, molding, fabric, pultruded profile, and others. On the basis of matrix type, the market is segmented into polymer matrix, carbon matrix, ceramic matrix, and others. On the basis of structure, the market is segmented into primary, secondary, and interior. On the basis of application, the market is classified into commercial aircraft, military aircraft, spacecraft, unmanned aerial vehicles, helicopters, and general aviation. On the basis of end-use, the market is segmented into original equipment manufacturers, and maintenance, repair, and overhaul providers. On the basis of region, the carbon fiber composite intermediates in aerospace market is analyzed across North America, Europe, Asia-Pacific, and LAMEA.

Prepreg is the dominant segment in terms of market size due to its extensive use in high-performance aerospace components, especially in the primary structures of aircraft. Its properties, such as superior strength-to-weight ratio and ease of use in automated processes, make it a preferred choice for aerospace manufacturers. However, pellets exhibit the fastest growth due to their increasing adoption in injection molding processes, which are gaining popularity in the aerospace sector for producing complex shapes with high precision and lower costs

The primary structure segment dominates the market, driven by the need for robust, lightweight materials in critical aircraft components such as wings and fuselage. The high demand for carbon fiber composites in these applications stems from the necessity to reduce aircraft weight and improve fuel efficiency. Furthermore, the secondary structure segment is growing rapidly as manufacturers seek to replace metal components in non-critical areas with lighter composites, thereby further reducing aircraft weight and improving efficiency.

The carbon matrix segment dominates and develops rapidly due to its excellent high-temperature performance, making it essential for aerospace applications where thermal resistance is critical, such as in engine components and heat shields.

Commercial aircraft is the leading application segment, driven by the continuous growth in air travel and the subsequent demand for new, fuel-efficient aircraft. The adoption of carbon fiber composites in commercial aircraft has been pivotal in reducing operational costs and meeting environmental regulations. In addition, the spacecraft segment is experiencing the fastest growth, driven by the surge in space exploration and satellite launches. The demand for lightweight, durable materials is crucial in reducing launch costs and improving mission longevity.

Original Equipment Manufacturers (OEMs) dominate the market as they are the primary producers of aircraft and spacecraft, necessitating large volumes of carbon fiber composites for new aircraft production. Furthermore, Maintenance, Repair, and Overhaul (MRO) providers are growing rapidly as the existing fleet of aircraft ages, requiring more frequent repairs and upgrades. The use of carbon fiber composites in repairs is becoming more common due to their superior performance characteristics.

North America is the dominant region due to the presence of major aerospace manufacturers such as Boeing and Lockheed Martin, as well as a strong focus on advanced materials and technologies. However, LAMEA (Latin America, Middle East, and Africa) region is growing the fastest, fueled by increase in investments in aerospace infrastructure and the adoption of advanced materials in emerging markets.

The major players operating in the carbon fiber composite intermediates in aerospace market include Toray Industries, inc., Mitsubishi Chemical Corporation, Hexcel Corporation, SGL Carbon, Teijin Limited., Solvay, Isovolta group, Saertex GmbH and CO. KG, Rock West Composites, Inc., and Huntsman corporation.

Toray Industries is a major player in the aerospace sector, primarily due to its advanced carbon fiber composites. As the world's largest producer of carbon fiber which has a global market share of around 35%, Toray's materials are extensively used in aircraft like the Boeing 787 Dreamliner, where they contribute to significant weight reductions and improved fuel efficiency.

Toray has also been involved in innovative projects such as the U.S. Army's Future Long Range Assault Aircraft (FLRAA) program. Its upgraded carbon fiber production line supports the manufacturing of lightweight, high-strength airframes for this next-generation aircraft. In addition, Toray employs materials informatics to develop carbon fiber-reinforced plastics (CFRP) with exceptional flame retardance and mechanical performance, further enhancing their aerospace applications

Key Benefits For Stakeholders

• This report provides a quantitative analysis of the market segments, current trends, estimations, and dynamics of the carbon fiber composite intermediates in aerospace market analysis from 2023 to 2033 to identify the prevailing carbon fiber composite intermediates in aerospace market opportunities.
• The market research is offered along with information related to key drivers, restraints, and opportunities.
• Porter's five forces analysis highlights the potency of buyers and suppliers to enable stakeholders make profit-oriented business decisions and strengthen their supplier-buyer network.
• In-depth analysis of the carbon fiber composite intermediates in aerospace market segmentation assists to determine the prevailing market opportunities.
• Major countries in each region are mapped according to their revenue contribution to the global market.
• Market player positioning facilitates benchmarking and provides a clear understanding of the present position of the market players.
• The report includes the analysis of the regional as well as global carbon fiber composite intermediates in aerospace market trends, key players, market segments, application areas, and market growth strategies.

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Key Market Segments

By Product Type

• Prepreg
• Pellets
• Molding
  • Molding Type
  • Sheet Molding Compound
  • Bulk Molding Compound
  • Resin Transfer Molding Compound
• Fabric
• Pultruded Profiles
• Others

By Structure

• Primary
• Secondary
• Interior

By Matrix Type

• Polymer Matrix
• Carbon Matrix
• Ceramic Matrix
• Others

By Application

• Commercial Aircraft
• Military Aircraft
• Spacecraft
• Unmanned Aerial Vehicles (UAVs)
• Helicopters
• General Aviation

By End-Use

• Original Equipment Manufacturers (OEMs)
• Maintenance, Repair, and Overhaul (MRO) Providers

By Region

• North America
  • U.S.
  • Canada
  • Mexico
• Europe
  • France
  • Germany
  • Italy
  • Spain
  • UK
  • Rest of Europe
• Asia-Pacific
  • China
  • Japan
  • India
  • South Korea
  • Australia
  • Rest of Asia-Pacific
• LAMEA
  • Brazil
  • South Africa
  • Saudi Arabia
  • Rest of LAMEA

Key Market Players:

• Hexcel Corporation
• Huntsman Corporation
• ISOVOLTA AG
• Mitsubishi Chemical Group Corporation.
• Rock West Composites, Inc.
• SAERTEX GmbH & Co.KG
• SGL Carbon
• Solvay
• TEIJIN LIMITED.
• TORAY INDUSTRIES, INC.

TABLE OF CONTENTS

CHAPTER 1: INTRODUCTION

• 1.1. Report description
• 1.2. Key market segments
• 1.3. Key benefits to the stakeholders
• 1.4. Research methodology
  • 1.4.1. Primary research
  • 1.4.2. Secondary research
  • 1.4.3. Analyst tools and models

CHAPTER 2: EXECUTIVE SUMMARY

• 2.1. CXO perspective

CHAPTER 3: MARKET OVERVIEW

• 3.1. Market definition and scope
• 3.2. Key findings
  • 3.2.1. Top impacting factors
  • 3.2.2. Top investment pockets
• 3.3. Porter's five forces analysis
  • 3.3.1. Moderate bargaining power of suppliers
  • 3.3.2. High threat of new entrants
  • 3.3.3. High threat of substitutes
  • 3.3.4. High intensity of rivalry
  • 3.3.5. Moderate bargaining power of buyers
• 3.4. Market dynamics
  • 3.4.1. Drivers
    • 3.4.1.1. Increase in demand for lightweight materials in the aerospace industry
    • 3.4.1.2. Growth of commercial and military aircraft production
  • 3.4.2. Restraints
    • 3.4.2.1. High production cost of carbon fiber composites
    • 3.4.2.2. Complex manufacturing process
  • 3.4.3. Opportunities
    • 3.4.3.1. Expansion in emerging markets
• 3.5. Average Selling Price
• 3.6. Value Chain Analysis
• 3.7. Regulatory Guidelines
• 3.8. Patent Landscape

CHAPTER 4: CARBON FIBER COMPOSITE INTERMEDIATES IN AEROSPACE MARKET, BY PRODUCT TYPE

• 4.1. Overview
  • 4.1.1. Market size and forecast
• 4.2. Prepreg
  • 4.2.1. Key market trends, growth factors and opportunities
  • 4.2.2. Market size and forecast, by region
  • 4.2.3. Market share analysis by country
• 4.3. Pellets
  • 4.3.1. Key market trends, growth factors and opportunities
  • 4.3.2. Market size and forecast, by region
  • 4.3.3. Market share analysis by country
• 4.4. Molding
  • 4.4.1. Key market trends, growth factors and opportunities
  • 4.4.2. Market size and forecast, by region
  • 4.4.3. Market share analysis by country
  • 4.4.4. Molding Carbon Fiber Composite Intermediates In Aerospace Market by Molding Type
• 4.5. Fabric
  • 4.5.1. Key market trends, growth factors and opportunities
  • 4.5.2. Market size and forecast, by region
  • 4.5.3. Market share analysis by country
• 4.6. Pultruded Profiles
  • 4.6.1. Key market trends, growth factors and opportunities
  • 4.6.2. Market size and forecast, by region
  • 4.6.3. Market share analysis by country
• 4.7. Others
  • 4.7.1. Key market trends, growth factors and opportunities
  • 4.7.2. Market size and forecast, by region
  • 4.7.3. Market share analysis by country

CHAPTER 5: CARBON FIBER COMPOSITE INTERMEDIATES IN AEROSPACE MARKET, BY STRUCTURE

• 5.1. Overview
  • 5.1.1. Market size and forecast
• 5.2. Primary
  • 5.2.1. Key market trends, growth factors and opportunities
  • 5.2.2. Market size and forecast, by region
  • 5.2.3. Market share analysis by country
• 5.3. Secondary
  • 5.3.1. Key market trends, growth factors and opportunities
  • 5.3.2. Market size and forecast, by region
  • 5.3.3. Market share analysis by country
• 5.4. Interior
  • 5.4.1. Key market trends, growth factors and opportunities
  • 5.4.2. Market size and forecast, by region
  • 5.4.3. Market share analysis by country

CHAPTER 6: CARBON FIBER COMPOSITE INTERMEDIATES IN AEROSPACE MARKET, BY MATRIX TYPE

• 6.1. Overview
  • 6.1.1. Market size and forecast
• 6.2. Polymer Matrix
  • 6.2.1. Key market trends, growth factors and opportunities
  • 6.2.2. Market size and forecast, by region
  • 6.2.3. Market share analysis by country
• 6.3. Carbon Matrix
  • 6.3.1. Key market trends, growth factors and opportunities
  • 6.3.2. Market size and forecast, by region
  • 6.3.3. Market share analysis by country
• 6.4. Ceramic Matrix
  • 6.4.1. Key market trends, growth factors and opportunities
  • 6.4.2. Market size and forecast, by region
  • 6.4.3. Market share analysis by country
• 6.5. Others
  • 6.5.1. Key market trends, growth factors and opportunities
  • 6.5.2. Market size and forecast, by region
  • 6.5.3. Market share analysis by country

CHAPTER 7: CARBON FIBER COMPOSITE INTERMEDIATES IN AEROSPACE MARKET, BY APPLICATION

• 7.1. Overview
  • 7.1.1. Market size and forecast
• 7.2. Commercial Aircraft
  • 7.2.1. Key market trends, growth factors and opportunities
  • 7.2.2. Market size and forecast, by region
  • 7.2.3. Market share analysis by country
• 7.3. Military Aircraft
  • 7.3.1. Key market trends, growth factors and opportunities
  • 7.3.2. Market size and forecast, by region
  • 7.3.3. Market share analysis by country
• 7.4. Spacecraft
  • 7.4.1. Key market trends, growth factors and opportunities
  • 7.4.2. Market size and forecast, by region
  • 7.4.3. Market share analysis by country
• 7.5. Unmanned Aerial Vehicles (UAVs)
  • 7.5.1. Key market trends, growth factors and opportunities
  • 7.5.2. Market size and forecast, by region
  • 7.5.3. Market share analysis by country
• 7.6. Helicopters
  • 7.6.1. Key market trends, growth factors and opportunities
  • 7.6.2. Market size and forecast, by region
  • 7.6.3. Market share analysis by country
• 7.7. General Aviation
  • 7.7.1. Key market trends, growth factors and opportunities
  • 7.7.2. Market size and forecast, by region
  • 7.7.3. Market share analysis by country

CHAPTER 8: CARBON FIBER COMPOSITE INTERMEDIATES IN AEROSPACE MARKET, BY END-USE

• 8.1. Overview
  • 8.1.1. Market size and forecast
• 8.2. Original Equipment Manufacturers (OEMs)
  • 8.2.1. Key market trends, growth factors and opportunities
  • 8.2.2. Market size and forecast, by region
  • 8.2.3. Market share analysis by country
• 8.3. Maintenance, Repair, and Overhaul (MRO) Providers
  • 8.3.1. Key market trends, growth factors and opportunities
  • 8.3.2. Market size and forecast, by region
  • 8.3.3. Market share analysis by country

CHAPTER 9: CARBON FIBER COMPOSITE INTERMEDIATES IN AEROSPACE MARKET, BY REGION

• 9.1. Overview
  • 9.1.1. Market size and forecast By Region
• 9.2. North America
  • 9.2.1. Key market trends, growth factors and opportunities
  • 9.2.2. Market size and forecast, by Product Type
  • 9.2.3. Market size and forecast, by Structure
  • 9.2.4. Market size and forecast, by Matrix Type
  • 9.2.5. Market size and forecast, by Application
  • 9.2.6. Market size and forecast, by End-Use
  • 9.2.7. Market size and forecast, by country
    • 9.2.7.1. U.S.
    • 9.2.7.1.1. Market size and forecast, by Product Type
    • 9.2.7.1.2. Market size and forecast, by Structure
    • 9.2.7.1.3. Market size and forecast, by Matrix Type
    • 9.2.7.1.4. Market size and forecast, by Application
    • 9.2.7.1.5. Market size and forecast, by End-Use
    • 9.2.7.2. Canada
    • 9.2.7.2.1. Market size and forecast, by Product Type
    • 9.2.7.2.2. Market size and forecast, by Structure
    • 9.2.7.2.3. Market size and forecast, by Matrix Type
    • 9.2.7.2.4. Market size and forecast, by Application
    • 9.2.7.2.5. Market size and forecast, by End-Use
    • 9.2.7.3. Mexico
    • 9.2.7.3.1. Market size and forecast, by Product Type
    • 9.2.7.3.2. Market size and forecast, by Structure
    • 9.2.7.3.3. Market size and forecast, by Matrix Type
    • 9.2.7.3.4. Market size and forecast, by Application
    • 9.2.7.3.5. Market size and forecast, by End-Use
• 9.3. Europe
  • 9.3.1. Key market trends, growth factors and opportunities
  • 9.3.2. Market size and forecast, by Product Type
  • 9.3.3. Market size and forecast, by Structure
  • 9.3.4. Market size and forecast, by Matrix Type
  • 9.3.5. Market size and forecast, by Application
  • 9.3.6. Market size and forecast, by End-Use
  • 9.3.7. Market size and forecast, by country
    • 9.3.7.1. France
    • 9.3.7.1.1. Market size and forecast, by Product Type
    • 9.3.7.1.2. Market size and forecast, by Structure
    • 9.3.7.1.3. Market size and forecast, by Matrix Type
    • 9.3.7.1.4. Market size and forecast, by Application
    • 9.3.7.1.5. Market size and forecast, by End-Use
    • 9.3.7.2. Germany
    • 9.3.7.2.1. Market size and forecast, by Product Type
    • 9.3.7.2.2. Market size and forecast, by Structure
    • 9.3.7.2.3. Market size and forecast, by Matrix Type
    • 9.3.7.2.4. Market size and forecast, by Application
    • 9.3.7.2.5. Market size and forecast, by End-Use
    • 9.3.7.3. Italy
    • 9.3.7.3.1. Market size and forecast, by Product Type
    • 9.3.7.3.2. Market size and forecast, by Structure
    • 9.3.7.3.3. Market size and forecast, by Matrix Type
    • 9.3.7.3.4. Market size and forecast, by Application
    • 9.3.7.3.5. Market size and forecast, by End-Use
    • 9.3.7.4. Spain
    • 9.3.7.4.1. Market size and forecast, by Product Type
    • 9.3.7.4.2. Market size and forecast, by Structure
    • 9.3.7.4.3. Market size and forecast, by Matrix Type
    • 9.3.7.4.4. Market size and forecast, by Application
    • 9.3.7.4.5. Market size and forecast, by End-Use
    • 9.3.7.5. UK
    • 9.3.7.5.1. Market size and forecast, by Product Type
    • 9.3.7.5.2. Market size and forecast, by Structure
    • 9.3.7.5.3. Market size and forecast, by Matrix Type
    • 9.3.7.5.4. Market size and forecast, by Application
    • 9.3.7.5.5. Market size and forecast, by End-Use
    • 9.3.7.6. Rest of Europe
    • 9.3.7.6.1. Market size and forecast, by Product Type
    • 9.3.7.6.2. Market size and forecast, by Structure
    • 9.3.7.6.3. Market size and forecast, by Matrix Type
    • 9.3.7.6.4. Market size and forecast, by Application
    • 9.3.7.6.5. Market size and forecast, by End-Use
• 9.4. Asia-Pacific
  • 9.4.1. Key market trends, growth factors and opportunities
  • 9.4.2. Market size and forecast, by Product Type
  • 9.4.3. Market size and forecast, by Structure
  • 9.4.4. Market size and forecast, by Matrix Type
  • 9.4.5. Market size and forecast, by Application
  • 9.4.6. Market size and forecast, by End-Use
  • 9.4.7. Market size and forecast, by country
    • 9.4.7.1. China
    • 9.4.7.1.1. Market size and forecast, by Product Type
    • 9.4.7.1.2. Market size and forecast, by Structure
    • 9.4.7.1.3. Market size and forecast, by Matrix Type
    • 9.4.7.1.4. Market size and forecast, by Application
    • 9.4.7.1.5. Market size and forecast, by End-Use
    • 9.4.7.2. Japan
    • 9.4.7.2.1. Market size and forecast, by Product Type
    • 9.4.7.2.2. Market size and forecast, by Structure
    • 9.4.7.2.3. Market size and forecast, by Matrix Type
    • 9.4.7.2.4. Market size and forecast, by Application
    • 9.4.7.2.5. Market size and forecast, by End-Use
    • 9.4.7.3. India
    • 9.4.7.3.1. Market size and forecast, by Product Type
    • 9.4.7.3.2. Market size and forecast, by Structure
    • 9.4.7.3.3. Market size and forecast, by Matrix Type
    • 9.4.7.3.4. Market size and forecast, by Application
    • 9.4.7.3.5. Market size and forecast, by End-Use
    • 9.4.7.4. South Korea
    • 9.4.7.4.1. Market size and forecast, by Product Type
    • 9.4.7.4.2. Market size and forecast, by Structure
    • 9.4.7.4.3. Market size and forecast, by Matrix Type
    • 9.4.7.4.4. Market size and forecast, by Application
    • 9.4.7.4.5. Market size and forecast, by End-Use
    • 9.4.7.5. Australia
    • 9.4.7.5.1. Market size and forecast, by Product Type
    • 9.4.7.5.2. Market size and forecast, by Structure
    • 9.4.7.5.3. Market size and forecast, by Matrix Type
    • 9.4.7.5.4. Market size and forecast, by Application
    • 9.4.7.5.5. Market size and forecast, by End-Use
    • 9.4.7.6. Rest of Asia-Pacific
    • 9.4.7.6.1. Market size and forecast, by Product Type
    • 9.4.7.6.2. Market size and forecast, by Structure
    • 9.4.7.6.3. Market size and forecast, by Matrix Type
    • 9.4.7.6.4. Market size and forecast, by Application
    • 9.4.7.6.5. Market size and forecast, by End-Use
• 9.5. LAMEA
  • 9.5.1. Key market trends, growth factors and opportunities
  • 9.5.2. Market size and forecast, by Product Type
  • 9.5.3. Market size and forecast, by Structure
  • 9.5.4. Market size and forecast, by Matrix Type
  • 9.5.5. Market size and forecast, by Application
  • 9.5.6. Market size and forecast, by End-Use
  • 9.5.7. Market size and forecast, by country
    • 9.5.7.1. Brazil
    • 9.5.7.1.1. Market size and forecast, by Product Type
    • 9.5.7.1.2. Market size and forecast, by Structure
    • 9.5.7.1.3. Market size and forecast, by Matrix Type
    • 9.5.7.1.4. Market size and forecast, by Application
    • 9.5.7.1.5. Market size and forecast, by End-Use
    • 9.5.7.2. South Africa
    • 9.5.7.2.1. Market size and forecast, by Product Type
    • 9.5.7.2.2. Market size and forecast, by Structure
    • 9.5.7.2.3. Market size and forecast, by Matrix Type
    • 9.5.7.2.4. Market size and forecast, by Application
    • 9.5.7.2.5. Market size and forecast, by End-Use
    • 9.5.7.3. Saudi Arabia
    • 9.5.7.3.1. Market size and forecast, by Product Type
    • 9.5.7.3.2. Market size and forecast, by Structure
    • 9.5.7.3.3. Market size and forecast, by Matrix Type
    • 9.5.7.3.4. Market size and forecast, by Application
    • 9.5.7.3.5. Market size and forecast, by End-Use
    • 9.5.7.4. Rest of LAMEA
    • 9.5.7.4.1. Market size and forecast, by Product Type
    • 9.5.7.4.2. Market size and forecast, by Structure
    • 9.5.7.4.3. Market size and forecast, by Matrix Type
    • 9.5.7.4.4. Market size and forecast, by Application
    • 9.5.7.4.5. Market size and forecast, by End-Use

CHAPTER 10: COMPETITIVE LANDSCAPE

• 10.1. Introduction
• 10.2. Top winning strategies
• 10.3. Product mapping of top 10 player
• 10.4. Competitive dashboard
• 10.5. Competitive heatmap
• 10.6. Top player positioning, 2023

CHAPTER 11: COMPANY PROFILES

• 11.1. TORAY INDUSTRIES, INC.
  • 11.1.1. Company overview
  • 11.1.2. Key executives
  • 11.1.3. Company snapshot
  • 11.1.4. Operating business segments
  • 11.1.5. Product portfolio
  • 11.1.6. Business performance
  • 11.1.7. Key strategic moves and developments
• 11.2. Mitsubishi Chemical Group Corporation.
  • 11.2.1. Company overview
  • 11.2.2. Key executives
  • 11.2.3. Company snapshot
  • 11.2.4. Operating business segments
  • 11.2.5. Product portfolio
  • 11.2.6. Business performance
  • 11.2.7. Key strategic moves and developments
• 11.3. Hexcel Corporation
  • 11.3.1. Company overview
  • 11.3.2. Key executives
  • 11.3.3. Company snapshot
  • 11.3.4. Operating business segments
  • 11.3.5. Product portfolio
  • 11.3.6. Business performance
• 11.4. SGL Carbon
  • 11.4.1. Company overview
  • 11.4.2. Key executives
  • 11.4.3. Company snapshot
  • 11.4.4. Operating business segments
  • 11.4.5. Product portfolio
  • 11.4.6. Business performance
• 11.5. TEIJIN LIMITED.
  • 11.5.1. Company overview
  • 11.5.2. Key executives
  • 11.5.3. Company snapshot
  • 11.5.4. Operating business segments
  • 11.5.5. Product portfolio
  • 11.5.6. Business performance
• 11.6. Solvay
  • 11.6.1. Company overview
  • 11.6.2. Key executives
  • 11.6.3. Company snapshot
  • 11.6.4. Operating business segments
  • 11.6.5. Product portfolio
  • 11.6.6. Business performance
• 11.7. ISOVOLTA AG
  • 11.7.1. Company overview
  • 11.7.2. Key executives
  • 11.7.3. Company snapshot
  • 11.7.4. Operating business segments
  • 11.7.5. Product portfolio
• 11.8. SAERTEX GmbH & Co.KG
  • 11.8.1. Company overview
  • 11.8.2. Key executives
  • 11.8.3. Company snapshot
  • 11.8.4. Operating business segments
  • 11.8.5. Product portfolio
• 11.9. Rock West Composites, Inc.
  • 11.9.1. Company overview
  • 11.9.2. Key executives
  • 11.9.3. Company snapshot
  • 11.9.4. Operating business segments
  • 11.9.5. Product portfolio
• 11.10. Huntsman Corporation
  • 11.10.1. Company overview
  • 11.10.2. Key executives
  • 11.10.3. Company snapshot
  • 11.10.4. Operating business segments
  • 11.10.5. Product portfolio
  • 11.10.6. Business performance