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Source our nanofiber additives in a range of grades and tailored chemical functionalities designed to fit your needs - and explore below how they can enhance your industrial applications.
Our nanofiber technology transforms paper and packaging into high-performance, sustainable solutions that rival plastics - without petrochemicals. By reinforcing paper at the molecular level, nanofibers create stronger, lighter packaging that reduces raw material use and cuts shipping costs. They deliver petrochemical-free barriers that naturally block oxygen, oil, and grease, replacing plastic-based coatings like EVOH and PVDC with a renewable, recyclable alternative. At the same time, nanofibers enable premium printability, producing smoother surfaces and superior ink adhesion without chemical primers, perfect for high-end branding and vibrant graphics. Beyond performance, nanofibers add built-in functionality for antimicrobial, UV-blocking, or flame-resistant coatings, giving businesses a single bio-based platform to meet sustainability regulations, reduce costs, and differentiate with eco-friendly packaging.
Our nanofibers bring next-generation performance to concrete and cementitious systems, enabling builders to build stronger, last longer, and do it naturally. By reinforcing the microstructure, nanofibers boost compressive and flexural strength by up to 30–40%, allowing for lighter structures with reduced cement volumes. They also enhance hydration and workability, providing nucleation sites for more efficient hydration, smoother mixes, and consistent finishing. At the same time, nanofibers improve freeze-thaw resistance and permeability, tightening the pore structure to lower chloride and sulfate ingress while reducing micro-cracking in harsh environments. Beyond strength and durability, nanofibers accelerate curing and early strength development, keep projects on schedule, and synergize with SCMs like fly ash and slag to lower clinker factor and embodied carbon. The result: greener concrete that cuts material use, extends infrastructure lifespan, and meets evolving sustainability standards.
Our nanofiber treatments bring together performance and sustainability, upgrading fabrics with natural, high-performance functionality, without relying on toxic chemistries. They deliver fire and UV resistance naturally, avoiding heavy metals and brominated or halogenated chemicals. Nanofibers also enhance moisture management, improving wicking and breathability for sportswear and technical textiles. At the same time, they strengthen fabrics while maintaining durability and softness, extending product life without compromising comfort or drape. By cutting down on additives and processing steps, these treatments meet consumer demand for safe, sustainable performance wear while offering brands a powerful way to differentiate with eco-friendly, high-value finishes.
Our nanofibers make agriculture smarter and more sustainable by enabling advanced delivery systems for fertilizers, pesticides, and soil health applications. Through controlled release, nutrients are encapsulated and delivered gradually, reducing leaching and waste while improving efficiency. Nanofibers also boost water retention, increasing soil’s ability to hold moisture and helping crops thrive even under dry or stressed conditions. At the same time, their bio-compatibility supports beneficial microbes and soil regeneration, ensuring that inputs are safe for plants and ecosystems. The result is lower input costs, higher yields, and farming practices aligned with the growing demand for regenerative agriculture solutions.
Our nanofiber technology brings cleaner chemistry and stronger protection to coatings by reducing reliance on petrochemical additives and delivering natural functionality. Nanofibers enhance barrier properties, providing oxygen and oil resistance that improves coating integrity and extends product life. They also optimize film formation and stability, improving dispersion, rheology, and surface smoothness for consistent, high-quality finishes. At the same time, nanofibers introduce fire and heat resistance, enabling advanced protective performance for both industrial and consumer applications. With reduced additive loads, improved performance, and sustainable chemistry, these coatings open new markets and deliver eco-friendly solutions without toxic trade-offs.
Our nanofiber technology transforms paper and packaging into high-performance, sustainable solutions that rival plastics - without petrochemicals. By reinforcing paper at the molecular level, nanofibers create stronger, lighter packaging that reduces raw material use and cuts shipping costs. They deliver petrochemical-free barriers that naturally block oxygen, oil, and grease, replacing plastic-based coatings like EVOH and PVDC with a renewable, recyclable alternative. At the same time, nanofibers enable premium printability, producing smoother surfaces and superior ink adhesion without chemical primers, perfect for high-end branding and vibrant graphics. Beyond performance, nanofibers add built-in functionality for antimicrobial, UV-blocking, or flame-resistant coatings, giving businesses a single bio-based platform to meet sustainability regulations, reduce costs, and differentiate with eco-friendly packaging.
Our nanofibers bring next-generation performance to concrete and cementitious systems, enabling builders to build stronger, last longer, and do it naturally. By reinforcing the microstructure, nanofibers boost compressive and flexural strength by up to 30–40%, allowing for lighter structures with reduced cement volumes. They also enhance hydration and workability, providing nucleation sites for more efficient hydration, smoother mixes, and consistent finishing. At the same time, nanofibers improve freeze-thaw resistance and permeability, tightening the pore structure to lower chloride and sulfate ingress while reducing micro-cracking in harsh environments. Beyond strength and durability, nanofibers accelerate curing and early strength development, keep projects on schedule, and synergize with SCMs like fly ash and slag to lower clinker factor and embodied carbon. The result: greener concrete that cuts material use, extends infrastructure lifespan, and meets evolving sustainability standards.
Our nanofiber treatments bring together performance and sustainability, upgrading fabrics with natural, high-performance functionality, without relying on toxic chemistries. They deliver fire and UV resistance naturally, avoiding heavy metals and brominated or halogenated chemicals. Nanofibers also enhance moisture management, improving wicking and breathability for sportswear and technical textiles. At the same time, they strengthen fabrics while maintaining durability and softness, extending product life without compromising comfort or drape. By cutting down on additives and processing steps, these treatments meet consumer demand for safe, sustainable performance wear while offering brands a powerful way to differentiate with eco-friendly, high-value finishes.
Our nanofibers make agriculture smarter and more sustainable by enabling advanced delivery systems for fertilizers, pesticides, and soil health applications. Through controlled release, nutrients are encapsulated and delivered gradually, reducing leaching and waste while improving efficiency. Nanofibers also boost water retention, increasing soil’s ability to hold moisture and helping crops thrive even under dry or stressed conditions. At the same time, their bio-compatibility supports beneficial microbes and soil regeneration, ensuring that inputs are safe for plants and ecosystems. The result is lower input costs, higher yields, and farming practices aligned with the growing demand for regenerative agriculture solutions.
Our nanofiber technology brings cleaner chemistry and stronger protection to coatings by reducing reliance on petrochemical additives and delivering natural functionality. Nanofibers enhance barrier properties, providing oxygen and oil resistance that improves coating integrity and extends product life. They also optimize film formation and stability, improving dispersion, rheology, and surface smoothness for consistent, high-quality finishes. At the same time, nanofibers introduce fire and heat resistance, enabling advanced protective performance for both industrial and consumer applications. With reduced additive loads, improved performance, and sustainable chemistry, these coatings open new markets and deliver eco-friendly solutions without toxic trade-offs.
Seabind™ (Charged) is an amazing additive for structural components like concrete. It introduces electrostatic repulsion, which prevents particle clumping and ensures uniform distribution in the mix. This improves workability, enhances cement hydration, and increases the strength and durability of the final structure.
Seabind™ (Charged) electrostatic interactions promote better adhesion at the interfaces, improving the cohesion within the material. Additionally, the high surface area of nanocellulose allows it to interact more extensively with surrounding materials, forming stronger physical and chemical bonds, which increases the overall structural integrity and durability of the composite.
Seabind™ (Charged) improves additive compatibility by providing electrostatic interactions that enhance the dispersion and effectiveness of superplasticizers, accelerators, or retarders, ensuring optimal performance while maintaining mix consistency.
Seabind™ (Charged) improves particle dispersion through electrostatic interactions, creating a more uniform mix and maximizing the efficiency of binders. This allows for a reduction in the amount of binder material needed while maintaining the structural integrity of the material, resulting in cost savings and more efficient resource use.
Seabind™ (Charged) is an amazing additive for structural components like concrete. It introduces electrostatic repulsion, which prevents particle clumping and ensures uniform distribution in the mix. This improves workability, enhances cement hydration, and increases the strength and durability of the final structure.
Seabind™ (Charged) electrostatic interactions promote better adhesion at the interfaces, improving the cohesion within the material. Additionally, the high surface area of nanocellulose allows it to interact more extensively with surrounding materials, forming stronger physical and chemical bonds, which increases the overall structural integrity and durability of the composite.
Seabind™ (Charged) improves additive compatibility by providing electrostatic interactions that enhance the dispersion and effectiveness of superplasticizers, accelerators, or retarders, ensuring optimal performance while maintaining mix consistency.
Seabind™ (Charged) improves particle dispersion through electrostatic interactions, creating a more uniform mix and maximizing the efficiency of binders. This allows for a reduction in the amount of binder material needed while maintaining the structural integrity of the material, resulting in cost savings and more efficient resource use.
Seabind™ (Charged) is an amazing additive for structural components like concrete. It introduces electrostatic repulsion, which prevents particle clumping and ensures uniform distribution in the mix. This improves workability, enhances cement hydration, and increases the strength and durability of the final structure.
Seabind™ (Charged) electrostatic interactions promote better adhesion at the interfaces, improving the cohesion within the material. Additionally, the high surface area of nanocellulose allows it to interact more extensively with surrounding materials, forming stronger physical and chemical bonds, which increases the overall structural integrity and durability of the composite.
Seabind™ (Charged) improves additive compatibility by providing electrostatic interactions that enhance the dispersion and effectiveness of superplasticizers, accelerators, or retarders, ensuring optimal performance while maintaining mix consistency.
Seabind™ (Charged) improves particle dispersion through electrostatic interactions, creating a more uniform mix and maximizing the efficiency of binders. This allows for a reduction in the amount of binder material needed while maintaining the structural integrity of the material, resulting in cost savings and more efficient resource use.
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