Our mission to more sustainable products
Unique solutions to eliminate C-F bonds from PPE’s. PFAS free nanofiber-based air permeable membranes by a combination of two technologies.
Electrospinning; Manufacturing highly tunable, customizable and lightweight nanofibers for several applications.
Electrospinning is a highly versatile technique for producing nanomaterials with excellent precision and flexibility. The process offers nanoscale precision, allowing the creation of fine fibers ideal for applications in fields like biomedicine and filtration. These electrospun fibers also provide a high surface area, enhancing their reactivity and making them valuable for energy storage, catalysis, and other chemical applications.
Moreover, electrospinning enables the fabrication of composite materials by combining different substances, leading to fibers with enhanced properties such as strength or conductivity. The technique is compatible with a wide range of materials, offering versatility in materials, from polymers to ceramics and biomaterials.
Lastly, electrospinning allows for the customization of properties, enabling the production of fibers with tailored characteristics for specific applications.
PECVD: Elevating surfaces, enhancing performance and redefining material boundaries
In PECVD, several key advantages make it a preferred method for thin film deposition in various applications. PECVD allows for the creation of highly uniform coatings, ensuring even layer thickness across complex substrates. This process can also produce hydrophobic and oleophobic surfaces, which are ideal for applications requiring water and oil resistance, such as protective coatings for electronics or medical devices. The coatings formed through PECVD offer excellent adhesion to a variety of materials, enhancing their durability and performance in harsh environments.
Additionally, high wash resistance ensures that PECVD films remain intact and functional even after repeated exposure to cleaning processes.
Lastly, PECVD is known for its reduced environmental impact compared to traditional deposition techniques, as it operates at lower temperatures and often uses less toxic chemicals, contributing to more sustainable manufacturing practices.