Top 50 Ceramic Matrix Composite in Europe

iCOMAT develops patented Rapid Tow Shearing (RTS) technology for the production of lightweight carbon fiber composite parts, enabling faster manufacturing with reduced defects. This process significantly lowers costs and enhances sustainability in aerospace, automotive, and space industries by producing stronger components that outperform traditional materials.

Blackwave specializes in lightweight carbon fiber reinforced plastics, utilizing advanced composite manufacturing techniques to enhance material strength and reduce weight. This technology addresses the need for durable yet lightweight materials in industries such as automotive and aerospace, improving performance and fuel efficiency.

Antefil Composite Tech produces microengineered hybrid fibers that combine glass reinforcement with meltable, recyclable thermoplastics, enabling the creation of lightweight composite structures. This technology eliminates the need for traditional resin infusion processes, addressing the inefficiencies and environmental concerns associated with unrecyclable resins in advanced composites.

Fairmat recycles carbon fiber composites into FairPly, a versatile and sustainable material designed for high-performance applications across various industries. This technology mitigates the environmental impact of carbon fiber waste, which is projected to reach 138 million tons in landfills over the next 50 years.

The startup develops ceramic flat membrane filtration technology for wastewater treatment, providing reliable alternatives for water and sewage management. Their solutions enhance operational efficiency and ensure compliance with environmental standards in industrial applications.

FibreCoat produces thermoplastic-coated and aluminium-coated fibres using patented coating technology for applications in composites and electromagnetic interference (EMI) shielding. Their materials provide affordable, damage-resistant solutions for electric vehicles, construction, and government sectors, enhancing thermal management and protecting against EM radiation.

Composite Recycling employs specialized processes to convert fiberglass reinforced plastics into reusable fibers, creating a closed-loop system for composite materials. This method significantly reduces the waste generated by traditional composite manufacturing, promoting sustainability in the industry.

LiqTech offers advanced silicon carbide (SiC) ceramic membrane filtration technology for purifying liquids and gases in demanding industrial applications. Their durable, chemically inert membranes handle harsh chemicals and high temperatures, reducing maintenance and operational costs in sectors like oil and gas, power generation, and chemical processing.

Bcomp provides lightweight, sustainable materials made from natural fibers for high-performance applications across industries. Their ampliTex and power-Ribs technologies reduce the environmental impact of products in automotive, marine, sports, and aerospace by offering a bio-based alternative to traditional materials.

Lineat utilizes reclaimed carbon fiber to create uni-directional, fiber-aligned tapes that facilitate the manufacturing of new composite components. This technology enables the recycling of carbon fiber, reducing waste and lowering the carbon footprint in industries such as aerospace and automotive.

Uplift360 develops chemical technologies to recycle waste aramid fibers and composite materials by selectively removing resin matrices and extracting petrochemical feedstock. This process transforms end-of-life products into renewed continuous fibers, reducing reliance on virgin materials and minimizing environmental impact in the defense, aerospace, and automotive sectors.

Space Forge manufactures advanced materials in microgravity, utilizing the unique conditions of space to eliminate contamination and enhance crystal formation in alloys. This approach addresses the limitations of terrestrial manufacturing processes, enabling the production of superior materials for applications in electronics, pharmaceuticals, and more.

Foundation Alloy utilizes patented elemental selection algorithms to engineer new classes of superalloys and refractories, achieving superior mechanical properties and reduced energy consumption in production. The company addresses the inefficiencies of traditional metal manufacturing by providing parts with up to 90% faster lead times and 50% lower energy use, enabling rapid advancements in aerospace and power generation technologies.

Nova Carbon develops high-performance semi-finished products from carbon fiber waste using a patented Long Fiber Realignment technology that preserves fiber length and integrity. This process addresses the significant issue of carbon fiber waste, which is largely landfilled or incinerated, by recycling valuable materials for various industries, including automotive and construction.

Uses artificial intelligence to accelerate the discovery and development of advanced materials by predicting their properties and performance based on computational models. This approach reduces the time and cost associated with traditional materials research, enabling faster innovation in industries such as manufacturing, energy, and electronics.

Lidrotec utilizes ultra-short pulse laser technology to achieve high-precision micro-manufacturing and material modification across various substrates. This technology enhances accuracy and efficiency in industrial applications, meeting the demand for improved processing capabilities.

Diamfab manufactures synthetic diamond semiconductors designed for high-power electronics and extreme conditions, offering superior thermal conductivity, radiation resistance, and high voltage tolerance. This technology addresses the limitations of traditional semiconductor materials, enabling more efficient and reliable performance in demanding applications such as quantum computing and power electronics.

The startup develops sustainable alternatives to critical materials using advanced material science techniques to reduce dependency on scarce resources. Their solutions address supply chain vulnerabilities and environmental concerns associated with traditional material sourcing.

Oxford Sigma develops engineered fusion core materials to enhance the operational lifespan of fusion pilot plants and facilitate the transition to commercial fusion power stations. The company provides materials technology and design services that address the challenges of energy security and climate change through the commercialization of fusion energy.

Cambridge Electric Cement (CEC) has developed a scalable process for recycling cement by co-producing clinker in electric arc furnaces, achieving zero carbon emissions in its production. This technology addresses the challenge of creating reactive cement components without associated emissions, enabling a sustainable alternative in the cement industry.

CompPair develops HealTech™ technology, which integrates self-healing capabilities into composite materials, allowing for rapid repairs and extending the lifespan of these structures. This approach addresses the issue of material waste in the composites industry by enabling the reuse and regeneration of damaged components, ultimately preserving their economic value.

SCALE develops bio-based composite materials that enhance performance while significantly reducing production costs and greenhouse gas emissions compared to traditional carbon fiber. By utilizing renewable resources and low-impact processes, SCALE addresses the environmental impact of advanced composites used in various industries, including automotive and sporting goods.

Graphene Composites develops graphene-aerogel composites for applications in ballistic protection and pathogen resistance. Their technology enhances material strength and reduces weight, addressing the need for more effective protective gear and antimicrobial solutions in various industries.

TETMET utilizes Adaptive Spatial Lattice Manufacturing (ASLM) to produce large-scale lattice structures that are lightweight, strong, and 100% circular, addressing the high costs and complexities of traditional solid material production. This decentralized, on-demand manufacturing process significantly reduces material usage, energy consumption, and logistics costs across various industries, including automotive and aerospace.

Compular develops software that utilizes computational chemistry to simulate and analyze atomistic trajectories and molecular structures, enabling precise predictions of material properties. This technology enhances material development by reducing reliance on trial-and-error methods, leading to higher lab trial success rates and faster product development cycles.

Nanogence specializes in the production of novel synthetic materials using advanced polymerization techniques to enhance durability and performance in construction applications. The company addresses the need for sustainable and high-performance materials that reduce environmental impact while meeting the rigorous demands of modern building projects.

The startup specializes in micromachining technology that fabricates custom products from a wide range of materials, enabling defect-free processing of brittle materials at wafer-scale and beyond. This technology facilitates rapid prototyping, significantly accelerating the product development cycle for manufacturers.

PlasmaBound utilizes Controlled Plasma Ablation (CPA) technology to enhance the structural integrity and weight efficiency of materials used in automotive and aerospace applications. This process enables manufacturers to create stronger and lighter components while reducing waste and improving sustainability in production.

The startup manufactures a fiber-strengthened carbon composite material that combines carbon composites with specially developed steel fibers to enhance impact resistance while maintaining low weight and high stiffness. This technology enables the production of durable and lightweight bicycle frames, providing cyclists with improved safety and longevity.

NematX specializes in industrial 3D printing using proprietary Nematic 3DP Technology and liquid crystal polymers (LCP), which are ten times stronger than PEEK and can withstand temperatures exceeding 250°C. The company provides high-precision additive manufacturing solutions for industries such as aerospace and medical, enabling the production of complex, durable parts suitable for harsh environments.

Arceon develops high-performance composite materials and structural solutions that enhance the durability and efficiency of industrial applications. By replacing traditional materials, the company enables manufacturers to lower production costs while improving product lifespan and reliability.

The startup manufactures sustainable biopolymer-inorganic composite materials inspired by natural substances like ivory and tooth enamel, eliminating the need for traditional ceramic firing. This innovation enables the ceramics sector to transition to greener production methods while maintaining material performance and scalability.

Plyable is a global marketplace for custom composite molds and components, utilizing a network of vetted suppliers and advanced AI to deliver precision tooling solutions up to 44% faster than traditional methods. The platform addresses the lengthy lead times in composite manufacturing by providing instant quotes and streamlined production processes, enabling rapid prototyping and large-scale production.

The startup develops a nanotechnology platform that collaborates with universities to fund research and commercialize materials for industrial applications, including advanced sensors and functional coatings. This approach addresses the need for innovative solutions in environmental and societal challenges by enabling the development of specialized technologies and materials.

Sintermat utilizes Spark Plasma Sintering technology to create lightweight, high-strength materials with three times the mechanical strength and twice the hardness of conventional options. These materials are designed for demanding applications in the packaging, defense, and industrial tooling sectors, offering components with significantly extended service life and reduced raw material usage.

This startup develops nano-based materials for industrial applications, utilizing nanotechnology to create durable electrical and thermal conductors and insulators. Their products enable the production of components that can withstand high temperatures through efficient methods like compression molding and vacuum bagging, reducing manufacturing costs and complexity.

The startup develops water-resistant biocomposite materials that can replace traditional composites like fiberglass and carbon fiber, as well as plastics and metals. These materials reduce the carbon footprint of manufacturing processes and enhance supply chain security by minimizing water absorption during production.

TechnoCarbon develops Pierre-Carbone, a patented low-carbon composite material that is five times more durable than steel and requires 50% less energy to produce than traditional materials. This technology provides a sustainable alternative for construction and infrastructure, significantly reducing greenhouse gas emissions and resource consumption.

The startup produces carbon-reinforced composites using a proprietary technology that enables the continuous printing of fiber composites with various matrices. This approach enhances mechanical performance across industries, addressing the need for stronger and more durable materials in manufacturing applications.

BlueLeaf engineers advanced composite materials that provide superior strength-to-weight ratios and enhanced durability for demanding applications. Our proprietary resin formulations and fiber architectures optimize structural integrity and extend component lifespan in aerospace, automotive, and defense sectors.

The startup specializes in passivation technology that enhances the performance of compound semiconductor devices through tailored surface engineering techniques. By optimizing substrate and chip manufacturing processes, the company enables clients to produce devices that are more efficient, reliable, and cost-effective.

This startup manufactures natural material products for luxury brands, research laboratories, and prototyping workshops, utilizing advanced material engineering techniques to enhance the properties of various natural substances. By reintegrating these materials into production processes, clients can unlock new creative applications and improve sustainability in their product offerings.

The startup develops nano and micromagnetic iron oxides and ferrites in powder form for the hydrothermal synthesis of nano-ferrites, enabling steel manufacturers to convert recycled ferrous waste into functional materials. This process reduces industrial waste in water streams while enhancing profitability for steel producers.

ELSA Industry engineers advanced composite materials and lightweight structures for aerospace applications. They provide tailored designs and high-quality manufacturing to support sustainable aviation and autonomous UAV development.

The startup manufactures structural composite materials that provide a lightweight, fully recyclable alternative to reinforced concrete and stiffened steel for construction applications. By offering factory-fabricated panels and modular units, the company enables contractors and builders to reduce material waste and labor costs while enhancing project sustainability.

HTMS specializes in the development of high-temperature composite materials designed for extreme environments, enhancing durability and performance in applications such as aerospace and automotive industries. The company addresses the need for reliable materials that can withstand elevated temperatures while maintaining structural integrity, thereby improving safety and efficiency in critical applications.

Continuum Composite Recycling utilizes proprietary mechanical transformation technology to convert end-of-life composite materials, such as wind turbine blades, into fully recyclable building products. This process addresses the significant issue of industrial composite waste by providing sustainable alternatives for the construction industry, which seeks to lower its carbon footprint.

The startup has developed a process for manufacturing cubic silicon carbide (3C SiC) that utilizes a one-step photocatalytic method, harnessing sunlight and water to produce hydrogen. This technology enables semiconductor manufacturers to create iridium-free electrolysis systems and cost-effective SiC wafers, facilitating the adoption of cubic silicon carbide in various applications.

The startup develops a ceramic fiber technology that utilizes nano-fiber composites to create flexible, non-brittle materials with temperature stability and electrical insulation properties. This technology enhances performance in applications such as microfiltration, catalyst support, and heat dissipation for electronics, enabling the design of novel products.

Spherecube utilizes a proprietary Thermal Laser Curing technology to automate the production of high-performance composite parts without the need for molds, significantly reducing material waste and production costs. This approach addresses the challenges of traditional composite manufacturing by enabling the creation of lightweight, complex geometries with enhanced mechanical properties.