Abstract: This invention relates to a solar-cell module backing layer obtained by co-extruding obtained by melt co-extruding (i) a first polymer composition comprising (a) a polyamide, (b) an elastomer and (c) an elastomer that contains groups that bond chemically and/or interact physically with the polyamide, and wherein the first polymer composition comprises from 10 to 90 wt. % of the polyamide (a) and from 10 to 90 wt. % of the elastomer (b) and (c) (of the total weight of polyamide (a) and elastomer (b) and (c) present in the first polymer composition) and (ii) a second polymer composition comprising from 50-98 wt. % of elastomer and from 0.15-5 wt. % of groups (based on the total weight of the second polymer composition) that bond chemically and/or interact physically with the solar cell and optionally with the first polymer composition.

Abstract: A method of coating a substrate is disclosed. The method comprising the steps of that includes providing a substrate having a first surface, providing a particle based coating composition comprising particles, applying the coating composition to at least a part of the first surface of the substrate, and converting the particle based coating composition on the first surface of the substrate into a functional coating having a thickness of 50 nm to 25 ?mas measured along across section in a scanning electron microscope (SEM), wherein the particle based coating composition comprises nanoparticle, and converting the particle based coating composition involves a high intensity energy source heating at least a part of the coating composition, wherein the high intensity energy source is selected from the group of certain CO2 lasers and flame arrays. Furthermore an apparatus for preparing a coating is disclosed.

Abstract: This invention relates to a solar-cell module backing layer obtained by co-extruding obtained by melt co-extruding (i) a first polymer composition comprising (a) a polyamide, (b) an elastomer and (c) an elastomer that contains groups that bond chemically and/or interact physically with the polyamide, and wherein the first polymer composition comprises from 10 to 90 wt. % of the polyamide (a) and from 10 to 90 wt. % of the elastomer (b) and (c) (of the total weight of polyamide (a) and elastomer (b) and (c) present in the first polymer composition) and (ii) a second polymer composition comprising from 50-98 wt. % of elastomer and from 0.15-5 wt. % of groups (based on the total weight of the second polymer composition) that bond chemically and/or interact physically with the solar cell and optionally with the first polymer composition.

Abstract: The current invention relates to a solar-cell module backing monolayer obtained by melt-extruding a polymer composition comprising (a) a polyamide, (b) an elastomer and (c) an elastomer that contains groups that bond chemically and/or interact physically with the polyamide, and wherein the elastomer constitutes the continuous phase of the polymer composition and the polyamide constitutes the dispersed phase of the polymer composition, characterized in that the polymer composition comprises from 10 to 50 wt. % of the polyamide (a) and from 50 to 90 wt. % of the elastomer (b) and (c) (of the total weight of polyamide (a) and elastomer (b) and (c) present in the polymer composition).

Abstract: The invention relates to a processes and compositions for preparing anti-reflective coatings.

Abstract: Single layer anti-reflective hard-coat and methods of making same are disclosed and in particular comprise a structured surface, preferably a nano-structured surface. The hard-coat preferably a hardness above 0.5 GPa, more preferably above 0.7 GPa and most preferably above 1.0 GPa as measured by nano-indentation and/or a reduced tensile modulus above 3 GPa, more preferably above 8.5 GPa or 20 GPa, most preferably above 40 GPa as measured by nano-indentation and/or a scratch resistance above 5 mJ ?m-3, preferably above 15 or 30 mJ ?m-3, preferably above 60 mJ ?m-3 as measured by nano-indentation, and/or contains an amount of inorganic nano-particles from 5 to 75 weight %, preferably from 15 to 50 weight % relative to the weight of the second material present in the hard-coat. Preferably, the spatial length scale of the refractive index gradient in the single layer hard-coat is between 10 and 1000 nm; in particular between 100 and 200 nm.

Abstract: Single layer anti-reflective hard-coat; in particular which comprises a structured surface, preferably a nano-structured surface. The hard-coat preferably a hardness above 0.5 GPa, more preferably above 0.7 GPa and most preferably above 1.0 GPa as measured by nano-indentation and/or a reduced tensile modulus above 3 GPa, more preferably above 8.5 GPa or 20 GPa, most preferably above 40 GPa as measured by nano-indentation and/or a scratch resistance above 5 mJ ?m?3, preferably above 15 or 30 mJ ?m?3, preferably above 60 mJ ?m?3 as measured by nano-indentation, and/or contains an amount of inorganic nano-particles from 5 to 75 weight %, preferably from 15 to 50 weight % relative to the weight of the second material present in the hard-coat. Preferably, the spatial length scale of the refractive index gradient in the single layer hard-coat is between 10 and 1000 nm; in particular between 100 and 200 nm.

Abstract: The invention relates to hydrophobic coatings comprising reactive inorganic nano-particles, as well as their use in industrial processes. These coatings combine hydrophobic or even super-hydrophobic properties with superior mechanical properties and easy proccessability. Some super-hydrophobic coatings may even have self-cleaning properties. These hydrophobic and super-hydrophobic coatings may be applied in the food industry, exterior or interior decoration, automobile industry and display industry. Also comprised within the invention are finished articles comprising a coating of inorganic nano-particles.