Provided a reinforced thermoplastic with long glass fiber that offered a noticeable improvement compared to short fiber in stiffness and strength properties Long Fiber Thermoplastics for Brackets and Latches Key benefits and data for long fiber thermoplastic (LFT) to replace metal for brackets and latches

OnForce™ Long Glass Fiber Nylon Composite provided a corrosion-resistant, long glass fiber-reinforced material for cleaner connector Fiber-Line™ Braiding Process Overview of  key features and fibers for Fiber-Line™ Braiding process

Fiber-Line Engineered Fibers - Products & Applications Fiber-Line™ engineered fiber solutions are designed to meet the most specific and demanding requirements Recommendations & key considerations for processing and part design with continuous fiber reinforced thermoplastics

Product Carbon Footprint To date we have completed over 1,000 product carbon footprint calculations. Product Carbon Footprint Calculations

Fiber-Line Fiber-Line Fiber-Line

CARPET PRODUCER N Y L O N C A R P E T • Antimicrobial effectiveness for residential and hospital carpets • Suitable for Bulked Continuous Filament (BCF) processed polyamide (nylon) • Limited impact on color • Quick development to address growing market needs for hygienic surface coverings • Developed efficient antimicrobial solution adapted to BCF processing for high-quality yarns • Reduced risk of discoloration with a smartbatch alternative • Leveraged global capabilities to offer quick development, trials and production quantities • Cesa™ Fiber Additives – antimicrobial additives KEY REQUIREMENTS WHY AVIENT?

Our performance was supported by strong demand for our Dyneema® fiber technology used in personal protection applications and raw material deflation. Examples include: • Dyneema®, the world’s strongest fiber™, enables unmatched levels of performance and protection for end-use applications, including ballistic personal protection, marine and sustainable infrastructure and outdoor sports • Unique technologies that improve the recyclability of products and enable recycled content to be incorporated, thus advancing a more circular economy • Light-weighting solutions that replace heavier traditional materials like metal, glass and wood, which can improve fuel efficiency in all modes of transportation and reduce carbon footprint • Sustainable infrastructure solutions that increase energy efficiency, renewable energy, natural resource conservation and fiber optic / 5G network accessibility Avient is certified ACC Responsible Care®, a founding member of the Alliance to End Plastic Waste and certified Great Place to Work®.

Long fiber composites, in particular, are well-suited for replacing metal, offering exceptional strength-to-weight ratio and the ease of injection molding, which can expand design options and streamline processing steps.   Advanced computer-aided engineering (CAE) software, when complemented by in-depth design and material knowledge, facilitates precise prediction of the behavior of fiber-reinforced polymer materials. For more technical details on the structural performance of reinforced polymers using CAE, automotive design engineers may access material data and models for Avient’s fiber-reinforced solutions using Hexagon’s Digimat-MX Tool.

Long fiber composites, in particular, are well-suited for replacing metal, offering exceptional strength-to-weight ratio and the ease of injection molding, which can expand design options and streamline processing steps.   Advanced computer-aided engineering (CAE) software, when complemented by in-depth design and material knowledge, facilitates precise prediction of the behavior of fiber-reinforced polymer materials. For more technical details on the structural performance of reinforced polymers using CAE, automotive design engineers may access material data and models for Avient’s fiber-reinforced solutions using Hexagon’s Digimat-MX Tool.

Compared to aluminum paddle shafts, fiber-reinforced composites reduce weight without sacrificing rigidity. Both ABS laminate sheet and fiber-reinforced composites produce a strong, stiff hull that won’t flex in rough water or when fastened down to a roof rack. Using micro-layering techniques with polymer-based synthetic fibers can generate an exceptionally durable personal flotation device fabric that is also breathable and lightweight.