Top 50 Ceramic Matrix Composite

This startup operates a vertically integrated manufacturing platform that utilizes robotics and additive manufacturing to produce advanced ceramics and composites. By optimizing production processes with integrated software, the company enables industries such as aerospace and medical to efficiently create critical components for demanding applications.

Cambium develops high-temperature biomaterials, including monomers and composites, for applications in defense, aerospace, and renewable energy. Their products provide protection against extreme heat and rapid thermal impacts, addressing the need for reliable materials in demanding environments.

Continuous Composites manufactures parts using its proprietary Continuous Fiber 3D Printing (CF3D®) technology, which combines high-performance composite materials with rapid curing thermoset resins for on-demand production. This approach reduces manufacturing costs and lead times while enabling complex geometries and limitless material combinations tailored to specific applications across various industries.

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.

ARRIS develops additive molding technology for the large-scale production of 3D-aligned continuous fiber thermoplastic composite parts, enhancing the strength and durability of products across various industries. This technology addresses the need for lightweight, high-performance materials in sectors such as aerospace, automotive, and consumer electronics, reducing lifecycle costs and improving sustainability.

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.

Axillon Aerospace provides end-to-end engineering and manufacturing for mission-critical aerospace components, specializing in advanced composites, engine parts, and electro-thermal ice protection systems. They integrate design, development, manufacturing, and testing to deliver optimized solutions for defense and commercial aviation programs.

The startup manufactures composite 3D printers that utilize continuous fiber reinforcement to produce customized parts for the composites fabrication sector. Their technology reduces lead times and costs by enabling efficient, end-to-end manufacturing with various material combinations.

Layup manufactures composite parts and the associated tooling, utilizing advanced production techniques to expedite the delivery process. The company aims to provide customers with parts faster than competitors can generate quotes, addressing the industry's need for quicker turnaround times.

EntroMat develops high entropy material (HEM) powders for various industrial applications. Their advanced materials offer enhanced performance properties compared to traditional metal powders, enabling new possibilities in manufacturing and engineering.

Boston Materials manufactures thermal interface materials and composite materials using patented Z-axis Fiber™ technology, which employs vertically aligned carbon fibers for efficient energy transfer. The company addresses performance and reliability issues in semiconductors, durability challenges in lightweight vehicles, and cost concerns in hydrogen fuel cells for heavy-duty applications.

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 manufactures chip glass substrates for the industrial sector using advanced glass processing techniques. Their products enhance the performance and durability of electronic components, addressing the need for high-quality substrates in various applications.

The startup develops printed electronics and battery materials utilizing proprietary carbon nanotube and ink coating technologies to create transparent heaters, antennas, and LED lighting. Their materials enhance the performance and versatility of electronic devices, addressing the need for more efficient and adaptable components in various applications.

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.

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.

Orbital Composites utilizes proprietary continuous-fiber 3D printing and hybrid manufacturing techniques to produce high-performance composite parts for aerospace, defense, and energy applications at automotive costs and rapid cycle times. The company addresses the need for efficient, scalable manufacturing solutions in a $163 billion composites market, enabling the production of advanced components for drones, hypersonics, and space exploration.

The startup develops composite building systems that utilize digital engineering and automated manufacturing to create complete structures without concrete, steel, or wood. This approach provides a cost-effective and environmentally sustainable alternative to traditional construction materials, enhancing safety and reducing environmental impact.

Arieca manufactures Liquid Metal Embedded Elastomers (LMEE), a thermally conductive rubber composite designed for high-performance thermal interface materials in the semiconductor industry. This technology addresses the challenge of managing increased power densities by providing low thermal resistance and reliability in high-volume manufacturing processes.

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.

Raven Space Systems manufactures 3D-printed reentry capsules using patented Microwave Assisted Deposition (MAD) technology, which enables rapid production of aerospace-grade composite structures with minimized labor and waste. This approach addresses the high costs and long lead times associated with traditional composite manufacturing in the aerospace industry.

Holy Technologies develops a digital production system for industrial-scale composite manufacturing that utilizes continuous fiber paths to enhance structural integrity while minimizing weight by up to 30%. This technology addresses the challenges of traditional composite methods by enabling efficient recycling and reducing production costs by up to 50%.

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.

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.

VOID Technologies specializes in developing advanced composite materials that enhance structural integrity and reduce weight in various applications. The company addresses the challenge of material inefficiency in industries such as aerospace and automotive, leading to improved performance and lower operational costs.

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.

MITO Material Solutions develops patented hybrid additives that functionalize materials like graphene and biomaterials to enhance the strength, durability, and flexibility of fiber-reinforced composites and thermoplastics. This technology enables manufacturers to achieve superior material performance without altering their existing production processes.

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.

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.

Reinhold Industries manufactures lightweight, corrosion-resistant composite and metallic structures for the aerospace and defense sectors, specializing in components for aircraft cabin interiors and military applications. Their products, including composite seatbacks and ablative components, enhance durability and performance while meeting stringent industry requirements.

Hand Technologies manufactures BODA-derived resins (BDR) for the rapid production of matrix composites, addressing the need for efficient and high-performance materials in various industries. Their technology enables faster production cycles and improved material properties, enhancing the overall manufacturing process.

Helicoid Industries develops biomimetic composite technology that enhances impact toughness and structural integrity while reducing weight and raw material costs. This technology addresses the limitations of conventional composite laminates by providing superior performance in applications across automotive, aerospace, and defense sectors.

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.

This company develops advanced materials and manufacturing processes for semiconductor and electric motor components. Their technology aims to improve the performance and efficiency of these critical components in various applications.

Vedasya specializes in the design and manufacturing of composite materials and storage solutions, focusing on high-performance applications in aerospace and defense. The company addresses the need for efficient and sustainable composite manufacturing technologies, including hydrogen storage tanks and advanced composite parts, to enhance operational capabilities in these sectors.

The startup utilizes its Rapid Alloy Design (RAD)™ platform, which combines AI and Multi-Scale Simulations to design and optimize new alloys 100 times faster than traditional methods. This technology addresses the high costs and lengthy timelines associated with materials engineering by delivering bespoke alloys tailored to specific performance requirements in various industries.

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.

The startup specializes in additive manufacturing systems that utilize its Liquid Ceramic Process (LCP) to create precise three-dimensional structures from ceramics and metals. This technology enables the production of accurate artificial teeth and dental prostheses, overcoming the limitations of traditional manufacturing methods.

WEAV3D Inc. utilizes a patented composite forming technology that integrates weaving and composite consolidation into an automated process, significantly reducing waste and cycle time. This technology enables the production of lightweight vehicle body structures and components at a cost reduction of 30 to 50% compared to traditional carbon fiber methods, addressing the need for more efficient and economical manufacturing in the automotive and construction industries.

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.

Future Comp manufactures custom carbon-fiber thermoplastic components, offering design and production solutions for diverse industries. Their technology enables efficient creation of lightweight, high-strength parts tailored to specific application requirements.

The startup develops polycrystals with variable chemical compositions that generate laser radiation and effectively dissipate heat. This technology enhances the efficiency of medical and industrial machines, reducing operational costs and simplifying their design.

This company manufactures large-scale composite structures for infrastructure and energy projects, offering a lightweight and durable alternative to traditional materials. Their proprietary fabrication process enables businesses to build strong structures while potentially saving time and resources.

Fourier is commercializing thermoformable ceramic matrix composites that enable the production of thin, thermally conductive dielectric sheets molded into complex geometries for thermal management applications. This technology addresses the limitations of traditional materials by providing scalable solutions for the aerospace, renewable energy, and electric vehicle industries.

This startup manufactures precision optics and ceramic components for the medical, defense, semiconductor, and energy sectors, utilizing advanced techniques in processing brittle materials like optical glasses and technical ceramics. Their products address the need for high-performance, reliable components that meet stringent industry standards and enhance operational efficiency.

The startup has developed a consolidation technique that enables the production of high-performance materials through flash sintering of powders, minimizing material loss during manufacturing. This method significantly reduces production time for applications in aeronautics, luxury goods, defense, and industrial sectors.

CelluXtreme develops bio-based composite materials using nanocellulose extracted from plants, produced through a water-based process that adheres to green chemistry principles. Their technology provides lightweight, recyclable solutions that enhance mechanical performance and thermal conductivity, addressing the industry's need for sustainable alternatives in composite applications.