Coatings

Plasma coatings, embossed or printed structures can be used to protect surfaces against ice formation. Examples of applications include aircraft wings or wind turbine rotor blades protected against icing. The IGB has also developed an easy-to-use self-adhesive anti-icing film.

At Fraunhofer IGB, we have developed chitosan-based water-repellent finishes that could replace PFAS finishes in the leisure textiles sector in the future. The technology has already been implemented on a larger scale and the coatings are also transferable to other materials, e.g. cardboard and paper.

Functional anti-fogging coatings using low-pressure plasma processes can be used to prevent a disturbing visual impression caused by condensation of water droplets. The deposition can be done on flat substrates as well as on 3D parts.

At Fraunhofer IGB, we produce barrier layers that enhance the barrier effect of the plastic polyethylene terephthalate (PET) against water vapor and oxygen by a factor of more than 1000 compared to the untreated material.

In most cases, fluid products such as food or personal care products cannot be completely removed from their packaging. At Fraunhofer IGB, we develop surface modifications for packaging materials that reduce the adhesion of filling goods.

The surface of contact lenses can be modified in order to achieve improved comfort and an almost closed film of lachrymal fluid can form. At the same time the formation of protein-containing deposits is reduced. The procedure can be transferred to all polymer surfaces requiring good wettability which come into contact with body fluids, such as stents and catheters.

To prevent biofilm formation, we are investigating the effect of naturally occurring antimicrobially active compounds such as plant extracts, cationic peptides and enzymes. We develop coating systems for long-term and targeted release and, especially in the case of biomolecules, for preserving their function over a longer period of time.

The colonization of surfaces with biological cells is important in cell culture technology or for the ingrowth of prosthetic implants. We develop strategies for the biologization of surfaces and modify biopolymers such as heparin, gelatine, hyaluronic acid so that they bind covalently or adsorptively to plastic or metal surfaces.

Another topic is to avoid uncontrolled protein adsorption.

We develop surface modifications or formulations to positively influence wound healing after skin injuries. By binding amino groups, surfaces are modified in such a way that primary human skin cells adhere and grow better. In addition, particle-based formulations can help to release active ingredients in wound dressings.

The adhesion between the substrate and an overlying layer plays a decisive role in bonding, printing and coatings such as painting and metallization. Several factors influence the adhesion properties and minimal surface contamination can drastically reduce adhesion values. In order to achieve good adhesion performance, the pre-treatment of surfaces using plasma technology proved to be an alternative to conventional procedures.

We achieve friction-reducing and chemical-resistant finishes with parylene coatings. Poly(para-xylylene), or parylene for short, is produced in a vacuum using a CVD process. Parylene can be used to coat a wide variety of substrate materials: from metals, plastics and elastomers to plants, insects and archaeological artifacts. As the process is characterized by excellent gap mobility, porous substrates such as paper and membranes can also be coated.

With our expertise in polymers, surfaces and coating technologies, we offer customers solutions that can be implemented quickly for the substitution of PFAS. Examples include hydrophobic finishes with non-stick plasma polymers as well as friction-reducing and chemical-resistant finishes (parylene, hydrocarbon/silicon organic-based plasma coatings).

At Fraunhofer IGB, we have developed chitosan-based water-repellent finishes that could replace PFAS finishes in the leisure textiles sector in the future. The technology has already been implemented on a larger scale and the coatings are also transferable to other materials, e.g. cardboard and paper.

The application areas of films for packaging or surface protection bring with them a great need for customized surface finishes. These include coatings with gas permeation barriers, but also the chemical finishing of surfaces to adjust wetting properties or bondability.

We develop selective coatings for gas sensors to selectively detect different gases and substances:

• Environmental gases (NO_x, SO₂)
• Volatile organic compounds (VOCs)
• Other difficult to measure molecules

We functionalize the surface of biosensors for the detection of biological components:

• Biochips / microarrays
• Immustick
• RiFS