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市场调查报告书
商品编码
1733641
先进材料市场:复合材料、功能薄膜和涂层、先进陶瓷(按地区划分),2026-2032 年Advanced Materials Market By Composite (Polymer Matrix Composites, Metal Matrix Composites, Ceramic Matrix Composites ), Functional Films and Coatings, Advanced Ceramics, & Region for 2026-2032 |
许多行业的快速技术进步和创新正在推动先进材料市场的需求。先进材料,包括奈米材料、生物材料、智慧材料和复合材料,具有强度、耐用性、轻盈性和改进的功能性等卓越性能。这些材料对于建立下一代产品和技术至关重要,使该行业的收益在 2024 年超过 780.4 亿美元,并在 2032 年达到约 1531.6 亿美元的估值。
推动对复杂材料的需求不断增长的另一个关键因素是人们越来越关注永续性和能源效率。工业界对减少环境影响、提高能源效率和促进永续发展的材料的需求日益增长,预计从 2026 年到 2032 年,复合年增长率将达到 9.70%。
先进材料市场定义/概述
先进材料是与传统材料相比具有更优良的品质和性能特征的人造物质。这些材料是根据特定规格定制的,并经常用于尖端技术和应用。其中包括奈米材料、复合材料、生物材料和智慧材料。例如,奈米材料是具有奈米级(十亿分之一公尺)结构的材料,具有明确的电学、光学和机械特性。
由于其卓越的品质和性能特点,先进材料正在改变许多领域。这些材料对于生产航太和国防工业中轻质、耐用和坚固的零件至关重要。例如,碳纤维复合材料广泛应用于飞机和太空船,以减轻重量同时保持强度,从而提高燃油效率和性能。
由于其独特的性能和能力,先进材料的未来应用有望改变许多行业。先进材料预计将对能源领域产生重大影响。例如,石墨烯、钙钛矿和先进的复合材料将改变能源产业。
航太工业日益增长的需求是先进材料市场的主要驱动力。随着飞机製造商寻求更轻、更坚固、更省油的设计,复合材料、先进合金和奈米材料等创新材料变得越来越重要。根据国际航空运输协会(IATA)的预测,到 2037 年,全球航空客运量将翻一番,达到每年 82 亿人次。波音公司预测,到 2037 年将需要 42,730 架新的民航机。航太业的永续性努力正在鼓励使用可以使飞机更轻、更省油的创新材料。
此外,航太工业正在迅速扩张,对精密材料的需求也随之增加。 NASA 2023财年预算为254亿美元,比上年度增加3%,显示该机构将继续投资于严重依赖先进材料的太空技术。根据太空基金会预测,全球太空经济规模将在2020年达到4,470亿美元,而摩根士丹利则表示,到2040年将达到1兆美元。据摩根士丹利称,预计到 2040 年这一数字将达到 1 兆美元。这种扩张可能会增加对能够承受太空恶劣条件的材料的需求。此外,美国国防部正在加大对高超音速技术的重视,2023财年累计高超音速研究的预算为47亿美元,这将进一步增加对能够承受恶劣条件的创新材料的需求。
原材料供应有限对先进材料业务构成了重大障碍,但它也鼓励创新和永续实践。一个关键驱动因素是高科技应用对稀土元素(REE)的需求不断增长。根据美国地质调查局预测,2023年全球稀土氧化物产量将达28万吨,其中中国占超过70%。这种供应集中可能会造成瓶颈并导致价格波动。例如,欧盟委员会预测,到2030年欧盟对稀土的需求将增加5倍,凸显了供应链多元化和开发替代资源的重要性。
另一个驱动力是对永续和可回收材料的追求。根据联合国环境规划署 (UNEP) 的数据,全球整体材料使用量预计将从 2011 年的 790 亿吨翻一番,达到 2060 年的 1,670 亿吨。这一趋势正在推动对生物基替代材料和更有效率的回收方法的研究。例如,美国能源局先进製造办公室正在投资超过4亿美元用于开发环保製造方法和材料的项目。此外,欧盟循环经济行动计画旨在2030年增加欧盟再生材料的使用,这将有助于缓解原材料供应的压力。
Rapid technological advances and innovations across numerous industries are driving the demand for the advanced materials market. Advanced materials which include nanomaterials, biomaterials, smart materials, and composites have superior performance qualities such as increased strength, durability, lightweight, and functionality. These materials are crucial for building next-generation products and technologies by enabling the market to surpass a revenue of USD 78.04 Billion valued in 2024 and reach a valuation of around USD 153.16 Billion by 2032.
Another key element driving the increase in demand for sophisticated materials is the growing emphasis on sustainability and energy efficiency. Industries are increasingly looking for materials that can reduce environmental impact, increase energy efficiency, and promote sustainable development by enabling the market to grow at a CAGR of 9.70 % from 2026 to 2032.
Advanced Materials Market: Definition/ Overview
Advanced materials are engineered substances that have better qualities and performance characteristics than traditional materials. These materials are tailored to specific specifications and are frequently employed in cutting-edge technology and applications. They include nanomaterials, composites, biomaterials, and smart materials. Nanomaterials, for example, are materials with structures at the nanoscale (one billionth of a meter) that have distinct electrical, optical, and mechanical properties.
Because of their better qualities and performance characteristics, advanced materials are transforming many sectors. These materials are crucial in the aerospace and defense industries for producing lightweight, durable, and high-strength components. For example, carbon fiber composites are widely utilized in aircraft and spacecraft to reduce weight while maintaining strength resulting in greater fuel efficiency and performance.
The future application of advanced materials promises substantial transformations across numerous industries owing to their unique features and capabilities. Advanced materials will have a significant impact on the realm of energy. For example, graphene, perovskites, and advanced composites are poised to transform the energy industry.
The aerospace industry's expanding need is a primary driver of the advanced materials market. As airplane makers seek lighter, stronger, and more fuel-efficient designs, innovative materials such as composites, advanced alloys, and nanomaterials become increasingly important. According to the International Air Transport Association (IATA), global air passenger traffic is predicted to double by 2037, to 8.2 billion people per year. This increase in demand needs the manufacturing of more aircraft with Boeing estimating a requirement for 42,730 new commercial aircraft by 2037. The aerospace industry's effort for sustainability encourages the use of innovative materials that can lower aircraft weight and enhance fuel efficiency.
Furthermore, the space exploration industry is expanding rapidly increasing the demand for sophisticated materials. NASA's budget for fiscal year 2023 is USD 25.4 Billion, up 3% from the previous year indicating that the agency will continue to spend on space technologies that rely largely on sophisticated materials. The global space economy reached USD 447 Billion in 2020, according to the Space Foundation, and is expected to reach USD 1 Trillion by 2040, according to Morgan Stanley. This expansion will increase the demand for materials that can survive severe conditions in space. Furthermore, the US Department of Defense's increased focus on hypersonic technology with a budget commitment of USD 4.7 Billion for hypersonic-related research in fiscal year 2023 will further drive the need for innovative materials capable of withstanding harsh conditions.
The restricted availability of raw materials presents substantial hurdles for the advanced materials business but it also encourages innovation and sustainable practices. One significant factor is the growing demand for rare earth elements (REEs) in high-tech applications. According to the United States Geological Survey, global rare earth oxide production will reach 280,000 metric tons in 2023, with China accounting for over 70% of this total output. This concentration of supply leads to possible bottlenecks and price instability. For example, the European Commission forecasts that the EU's demand for rare earth elements is predicted to increase fivefold by 2030 emphasizing the critical need for supply chain diversity and the development of alternative resources.
Another motivator is the movement toward sustainable and recyclable materials. According to the United Nations Environment Programme, worldwide material use is expected to more than double from 79 billion tons in 2011 to 167 billion tons by 2060. This trend is driving research into bio-based alternatives and more efficient recycling methods. For example, the Advanced Manufacturing Office of the United States Department of Energy has invested more than USD 400 Million in programs to develop environmentally friendly manufacturing methods and materials. Furthermore, the European Union's Circular Economy Action Plan seeks to increase the usage of recycled materials in the EU by 2030, thus alleviating some of the pressure on raw material availability.
Polymer Matrix Composites (PMCs) dominate the advanced materials industry due to their broad application across industries and favorable features. PMCs, which are made of a polymer matrix reinforced with fibers like carbon, glass, or aramid, are popular because of their high strength-to-weight ratio, corrosion resistance, and design flexibility. These properties make PMCs particularly attractive in industries including aerospace, automotive, and sports equipment where weight reduction while retaining structural integrity is critical. For example, in the aerospace industry, PMCs are widely utilized in the manufacturing of aircraft components like fuselages, wings, and tail sections because they dramatically reduce overall aircraft weight resulting in improved fuel efficiency and performance.
PMCs' supremacy is due to their versatility and low cost of creating complicated forms and structures. The simplicity of molding and shaping PMCs allows for increased design flexibility allowing producers to make complicated pieces that would be difficult to create with standard materials. This adaptability is especially useful in the sports equipment market where personalized and ergonomically designed goods are critical for peak performance. PMCs' cost-effectiveness which stems from lower raw material costs and simpler production procedures than metal and ceramic composites, reinforces their market dominance.
Non-oxide ceramics are growing as the leading segment owing to their better mechanical qualities and high thermal resistance. Non-oxide ceramics including silicon carbide (SiC), silicon nitride (Si3N4), and boron nitride (BN) have excellent strength, hardness, and endurance making them perfect for demanding applications in a variety of high-performance sectors. These materials can tolerate severe temperatures with little deterioration, and their low thermal expansion coefficients provide dimensional stability under thermal stress. This makes non-oxide ceramics especially desirable in industries such as aircraft, automotive, and industrial manufacturing where components must work dependably in hostile environments.
Non-oxide ceramics are gaining traction in the electronics industry where their superior thermal and electrical qualities are critical. Silicon nitride and boron nitride, for example, are commonly utilized in semiconductor fabrication and advanced electrical equipment. Silicon nitride is an ideal material for electronic substrates and heat sinks due to its high thermal conductivity and electrical insulating qualities which help to regulate heat in high-power electronics while also boosting device performance and lifetime. Boron nitride which has a unique mix of thermal conductivity and electrical insulation is employed in thermal management applications such as heat spreaders and electronic device insulators.
The aerospace and defense sectors dominate the North American advanced materials market, with composites playing an important role in lightweight and high-performance applications. The region's dominance in these industries significantly drives up demand for advanced composites.
The aircraft industry is a significant driver of advanced composites in North America. The Aerospace Industries Association estimates that the U.S. aerospace and military industry will contribute $892 billion to the economy in 2022, accounting for 1.8% of total GDP. The Federal Aviation Administration (FAA) expects the total commercial aircraft fleet to rise from 7,690 in 2021 to 10,555 in 2042, showing a constant growth in demand for lightweight materials. Advanced composites, noted for their high strength-to-weight ratio, are critical to increasing fuel efficiency and lowering emissions.
The drive for efficiency is bolstered by the International Civil Aviation Organization's goal of achieving carbon-neutral expansion by 2020. In the defense sector, the US Department of Defense's USD 842 Billion budget request for fiscal year 2024 including a sizable amount dedicated to research and development demonstrates the sustained investment in advanced materials for military uses. The automotive industry also adds to the rising need for sophisticated composites. The US Environmental Protection Agency's Corporate Average Fuel Economy (CAFE) requirements which seek to attain an industry-wide objective of 49 mpg for passenger cars and light trucks by 2026 are encouraging manufacturers to use lightweight materials.
The Asia-Pacific region is expected to be the fastest-growing market for advanced materials driven mostly by rising demand for high-end automotive components. This expansion is likely to surpass other regions because of fast industrialization and rising disposable income in China, Japan, and South Korea. The need for high-end automotive products is a major driver of the Asia-Pacific advanced materials industry. This is supported by several important elements and statistics. First, the International Organization of Motor Vehicle Manufacturers (OICA) reports that China alone will generate over 27 million vehicles in 2021, accounting for around 32.5% of global vehicle production. The China Passenger Car Association estimated that the luxury car segment in China will grow by 80% in 2021.
According to the International Energy Agency, China sold half of the world's electric vehicles in 2021, with 3.3 million units sold. EVs necessitate sophisticated materials for lightweight construction and battery technology which further fuels the market. According to Japan's "Green Growth Strategy," the government aims to have all new automobile sales be electric by 2035. This strategy is designed to speed up the adoption of innovative materials in the automotive industry. In addition, the Asia Pacific region is seeing significant investment in advanced material research and development.
The advanced materials market is a dynamic and competitive space, characterized by a diverse range of players vying for market share. These players are on the run for solidifying their presence through the adoption of strategic plans such as collaborations, mergers, acquisitions, and political support. The organizations are focusing on innovating their product line to serve the vast population in diverse regions.
Some of the prominent players operating in the advanced materials market include:
Momentive Performance Materials, Inc.
BASF SE
DowDuPont, Inc.
Morgan Advanced Materials
Hanwha Group
PyroGenesis Canada, Inc.
Cytech Products, Inc.
Akzo Nobel N.V.
Hexcel Corporation
In February 2023, Covestro AG announced plans to establish a thermoplastic polyurethanes (TPU) facility in Zhuhai, China. This would be the company's largest investment in the TPU industry, costing in the low three-digit millions of Euros.
In February 2023, Covestro AG introduced Makrolon 3638 polycarbonate, an ultra-durable polymer for healthcare and life science applications.