Green Chemistry Functionalization
Using a sustainable green chemistry process, we modify cellulose nanofibrils and functionalize them with lactic acid, with zero toxic reagents and low environmental impact.
Lactic acid grafting →
XyloTech develops advanced nanocellulose technologies that bridge sustainability and performance, enabling the next generation of lightweight, renewable, and industrially scalable materials.
At XyloTech, we envision a future where renewable materials are no longer viewed as alternatives, but as the benchmark for performance, innovation, and industrial excellence. We believe that the next generation of advanced materials will emerge from the intelligent combination of nature's most abundant resources and cutting edge material science. Through continuous innovation, we aim to redefine how materials are designed, engineered, and manufactured, enabling industries to build stronger, lighter, and more sustainable products for a rapidly evolving world.
Our mission is to unlock the full potential of cellulose and other renewable resources through breakthrough green chemistry and material engineering. By developing scalable, high performance bio based materials with superior functionality and industrial compatibility, we aim to accelerate the world's transition toward a circular and low carbon economy. Through scientific excellence, responsible innovation, and strategic partnerships, XyloTech is committed to transforming renewable materials into commercially viable solutions that create lasting value for industry, society, and future generations.
Using a sustainable green chemistry process, we modify cellulose nanofibrils and functionalize them with lactic acid, with zero toxic reagents and low environmental impact.
Lactic acid grafting →The functionalized nanofibrils are engineered to integrate cleanly with polymer matrices, improving dispersion, compatibility, and mechanical performance.
Drop in polymer compatibility →
Composites
Reinforcement additives that boost mechanical performance across PLA and polymer masterbatches.
Lightweight biocomposite interiors and structural parts that cut weight without compromising strength.
