Streamlined product development services through Avient Design • Color inspiration and technical guidance from ColorWorks™ Design & Technology Centers • Risk mitigation through invaluable regulatory compliance support • Accelerated commercialization with UL testing and part validation, and UL- recognized colorants FOCUS AREA APPLICATIONS KEY REQUIREMENTS TECHNOLOGIES Visual Aesthetics • User interfaces and touchpoints • Interactive touch screens • Lighting • Side panels and base plates • Cables • Closeouts • Informed color choices and customization options • Visual appeal for brand integrity • High- and low- gloss finishes • Consistent physical performance and dimensional stability • Special effect colorants • Smartbatch Combination Colorants & Additives • Custom and pre-colored formulations • ColorWorks Design & Technology Centers Outdoor Durability & Longevity • Ventilation panels • Closeouts • Cable retractors • Interactive touch screens • Outdoor weathering • Extreme (hot/cold) temperature resistance • Flexibility and ductility • Impact resistance • Chemical resistance • UL-recognized materials • Flame retardant formulations • Impact modifiers • Surface energy modifiers • EMI/RFI shielding solutions • Thermal and electrical management technology Health & Hygiene • User interfaces and touchpoints • Cables • Sockets • Plugs and adaptors • Filters • Kiosks • Microbial and fungal efficacy • Safe to touch • Visual clarity • Surface energy modifiers • Antimicrobial and anti- fungal solutions Sustainability • Structural panels • Connectors and electrical components • Thermal modules • Lighting • Receptacles • Reduced part weight or materials consumed • Recyclability • VOC reduction • PCR incorporation • Lower carbon footprint • Chemical foaming agents • Molded-in color (MIC) metallics • Laser marking technologies • Eco-conscious raw materials • Bio-derived technologies • Post-consumer recycled (PCR) content • Lower carbon footprint solutions 1.844.4AVIENT www.avient.com Copyright © 2023, Avient Corporation.

The E unit provides users with all the core innovations of FlexOne linked to a familiar analogue interface. Q/P units come with touch screen interface systems and a range of additional technology features for more complex material handling needs.

Here, continuous fibers, such as glass or carbon, are pulled through a thermoset resin bath, such as epoxy, polyester, or vinyl ester, and then formed into a desired shape using a die. Materials and processes such as fiber type, fiber volume, resin type, and surface veils and treatments can be engineered to meet specific properties and application requirements.  This means that they are weaker in the direction perpendicular to the fibers.

Here, continuous fibers, such as glass or carbon, are pulled through a thermoset resin bath, such as epoxy, polyester, or vinyl ester, and then formed into a desired shape using a die. Materials and processes such as fiber type, fiber volume, resin type, and surface veils and treatments can be engineered to meet specific properties and application requirements.  This means that they are weaker in the direction perpendicular to the fibers.

Here, continuous fibers, such as glass or carbon, are pulled through a thermoset resin bath, such as epoxy, polyester, or vinyl ester, and then formed into a desired shape using a die. Materials and processes such as fiber type, fiber volume, resin type, and surface veils and treatments can be engineered to meet specific properties and application requirements.  This means that they are weaker in the direction perpendicular to the fibers.

Maxxam™ BIO Bio-Based Polyolefin Formulations Maxxam™ BIO polyolefins are formulated with bio-based polyolefin resin and/or 10–50% natural filler from renewable plant sources, including olive seed based powder and cellulose fiber. To satisfy required performance characteristics they can be filled and reinforced with glass fiber, minerals, impact modifiers, colorants and stabilizer systems. KEY CHARACTERISTICS Formulated with bio-based resin and/or 10–50% filler from renewable plant sources, Maxxam BIO formulations: • Reduce product carbon footprint • Achieve equivalent performance to standard polyolefin formulations • Provide good stiffness, durability, impact resistance and UV stability • Deliver good surface finish and are easy to color • Enable customized performance characteristics depending on application need • Offer food contact compliance MARKETS AND APPLICATIONS Maxxam BIO formulations are suitable for use across many industries and applications where traditional polyolefin materials are used, including: • Transportation Interior Applications - Decorative profiles, trunk side liners, pillars, T-cup • Industrial - Structural parts, furniture • Consumer - Household goods, personal care items, packaging, office supplies, food contact applications • Electrical and Electronic – Housings, buttons, junction boxes SUSTAINABILITY BENEFITS • Formulated with bio-based resin and/or 10–50% natural filler • Utilize natural filler from renewable plant sources including olive seed based powder and cellulose fiber • Offer a lower product carbon footprint compared to traditional petroleum-based feedstock • Can be recycled at end of life PRODUCT BULLETIN CHARACTERISTICS UNITS Maxxam BIO MX5200-5036 Natural FD Maxxam BIO MX5200-5030 Natural FD Maxxam BIO MX5200-5030 Natural FD X1 Maxxam BIO MX5200-5001 Maxxam BIO MX5200-5033 Maxxam BIO MX5200-5034 Maxxam BIO MX5200-5035 Filler/Reinforcement Unfilled Unfilled Unfilled 30% Glass Fiber 10% 20% 30% Density (ISO 1183) g/cm 0.90 0.90 0.90 1.12 0.96 1.03 1.12 Tensile Modulus (ISO 527-1) @ 23°C MPa 1500 1000 1000 6400 1350 1650 2100 Tensile Stress (ISO 527-2) @ 23°C MPa 27.0 20.0 20.0 75.0 13.0 14.0 15.0 Tensile Strain at Break % 5 50 50 3.0 50 37 18 Charpy Notched (ISO 179) kJ/m 5 20 25 10 12 10 10 CHARACTERISTICS UNITS Maxxam BIO MX5200-5023 RS HS HI Natural 70 Maxxam BIO MX5200-5025 RS HS Natural 70 Maxxam BIO MX5200-5004 RS HS Maxxam BIO MX5200-5003 RS Maxxam BIO MX5200-5009 RS HS Natural 70 Maxxam BIO MX5200-5024 RS HS Maxxam BIO MX5200-5022 RS HS Filler/Reinforcement 15% Olive Seed Based 25% Olive Seed Based 30% Olive Seed 10% 35% Olive Seed 5% 15% Olive Seed 17% Glass Fiber/ 20% Olive Seed 20% Glass/ 10% Olive Seed 20% Density (ISO 1183) g/ccm 1.00 1.15 1.10 1.07 1.09 1.25 1.10 Tensile Modulus (ISO 527-1) @ 23°C MPa 1750 2000 2700 2500 3800 3500 4100 Tensile Stress at Break MPa 21.0 20.0 30.0 20.0 40.0 35.0 42.0 Tensile Strain at Break % 24 5 3 5 3 4 2 Notched Izod (ISO 180) kJ/m 15 7 3 2 5 15 7 MAXXAM BIO POLYOLEFINS – BIO-BASED RESIN – TECHNICAL PERFORMANCE MAXXAM BIO POLYOLEFINS – OLIVE SEED BASED FILLER – TECHNICAL PERFORMANCE CHARACTERISTICS UNITS Maxxam BIO MX5200-5029 NF HI UV Black X1 Maxxam BIO MX5200-5032 NFS UV Natural Maxxam BIO  MX5200-5020 NF/NFS UV Natural X1​ Maxxam BIO MX5200-5016 NF Natural Filler/Reinforcement 10% Cellulose Fiber 20% Cellulose Fiber 30% Cellulose Fiber 40% Cellulose Fiber Density (ISO 1183) g/ccm 0.95 1.00 1.02 1.07 Tensile Modulus ISO 527-1) @ 23°C MPa 1550 1750 2640 3600 Tensile Stress at Break (ISO 527-2) @ 23°C MPa 33 30 48 55 Tensile Strain at Break (ISO 527-2) @ 23°C % 8 12 9 4 Charpy Notched Impact Strength (ISO 179/1eA) kJ/m2 5 6 5 5 Charpy Unnotched Impact Strength (ISO 179/1eU) kJ/m2 33 49 38 30 MAXXAM BIO POLYOLEFINS – CELLULOSE FIBER FILLER – TECHNICAL PERFORMANCE Copyright © 2023, Avient Corporation.

Long Fiber Thermoplastics (LFT) for Brackets and Latches Unlock opportunities for cost savings, lightweighting, & production efficiencies Brackets and latches are traditionally made of cast aluminum or stamped steel. Long fiber thermoplastics (LFT) combine the structural integrity of metals with the lighter weight and cost-effectiveness of thermoplastic composites. Complēt™ long glass, long carbon, and hybrid fiber solutions available in a wide array of engineering polymer matrices, including PA66, PA6, ETPU, PPA, PPS, PES, PEI, PK, and PEEK • OnForce™ long glass fiber reinforced polypropylenes • Full suite of design and engineering services that include structural design and fiber orientation consultations and modeling, CAE analysis, prototyping, and more STRENGTH-TO-WEIGHT RATIO OF LFT VS METALS m eg ap as ca l gram /cubic centim eter 250 200 150 100 50 0 9.00 8.00 7.00 6.00 5.00 4.00 3.00 2.00 1.00 0.00 Zam ak 3 Stainless Steel 304 Titanium #2 plēt LCF40-PP plēt LGF60-TPU OnForce LGF50-PP Alum inum A380 M agnesium AZ91D plēt LCF50-PA66 plēt LGF60-PA66 plēt LCF50-TPU Specific Strength Density Metal Long Glass Fiber Long Carbon Fiber 1.844.4AVIENT www.avient.com Copyright © 2025, Avient Corporation.

However, an ongoing challenge, especially for high-end products with demanding aesthetic requirements, is to prevent adhesive residue when the protective film is removed. Versaflex™ CF 6668 low adhesion build-up TPE for protective film meets that need. The formulation delivers high initial adhesion on steel, PMMA, and various other substrates, yet offers low adhesion build-up to reduce the risk of residue when peeling off film.

Complēt™ REC Long Fiber Reinforced Composites Incorporating Recycled Resin The Complēt™ REC portfolio consists of long fiber reinforced composites incorporating post-consumer recycled (PCR) nylon 6 resin, post-industrial recycled (PIR) nylon 66 resin, and PIR thermoplastic polyurethane (TPU) resin. They process easily across all standard fiber loading ranges of long glass, long carbon, or hybrid combinations of fiber. TECHNICAL BULLETIN Sustainability Spotlight PERFORMANCE COMPARISON Long fiber composites can be custom formulated with varying levels of recycled resin as well as varying levels of fiber reinforcement to balance your performance and sustainability goals.

Fiber Colorants Fiber Additives Fiber-Line™ Engineered Synthetic Fiber Products