The invention relates to a coated glass substrate or glass ceramic substrate with resistant, multi-functional surface properties, including a combination of anti-microbial, anti-reflective and anti-fingerprint properties, or a combination of anti-microbial, anti-reflective and anti-fingerprint properties where the substrate is chemically pre-stressed, or a combination of anti-microbial and anti-reflective properties where the substrate is chemically pre-stressed. The coated glass substrate or glass ceramic substrate exhibits a unique combination of functions which are permanently present and do not exert a negative effect on each other.

A material includes a glass sheet coated on at least part of one of its faces with a stack of thin layers, the stack being coated on at least part of its surface with an enamel layer including zinc and less than 5% by weight of bismuth oxide, the stack further including, in contact with the enamel layer, a layer, called contact layer, which is based on an oxide, the physical thickness of the contact layer being at least 5 nm.

A method for producing a layer for coating the inner surface of a container and a glass or plastic container obtained by said method, wherein said container is suitable for containing products biocompatible with humans and/or animals. The method includes: forming a solution containing a solvent, water, a molecular precursor comprising alkoxy groups and an acid as a catalyst, mixing said solution to initiate hydrolysis and condensation, applying the resulting solution onto at least one portion of the inner surface of the container, while the solution is in the process of gelling, the resulting applied solution is then dried at a temperature for a predetermined time, before curing. The acid is citric acid, wherein said citric acid is at a concentration of less than 6 mol/l, and in that the solution comprises less than 1.5 units of precursor for each volume unit of acid.

A transparent glass or ceramic or glass-ceramic substrate, coated with a functional layer or with a stack of at least two functional layers, the functional layer or at least one of the functional layers of the stack being porous and made of an inorganic material M1, wherein the or at least one of the porous functional layer(s) of inorganic material M1 has, at the surface of at least one portion of the pores thereof, at least one inorganic material M2 different from M1.

Provided is a transparent substrate with a coating film having excellent ultraviolet absorbing ability and scratch resistance while maintaining visible light transmittance at high level. The transparent substrate with the coating film includes a transparent substrate, and a coating film formed at least at a part of a surface of the transparent substrate. The coating film contains a silicon oxide matrix and a specific ultraviolet absorbent, and has a thickness of 3 to 10 μm. The transparent substrate with the coating film has a transmittance of light with a wavelength of 400 nm of 10% or less, and a visible light transmittance of 50% or more, no scratch is visually recognized by a specific scratch resistance test for surface of the coating film, and a value where YI of the transparent substrate is subtracted from YI of the transparent substrate with the coating film is 10 or less.

Described is in particular a method of heat treatment of a material layer (102) of a material sandwich (100) comprising the material layer (102) and a substrate (104), wherein the substrate (104) comprises a silicon-oxygen compound and the material layer (102) comprises a silicon-oxygen compound, the method comprising irradiating the material layer (102) with a pulsed laser beam (114) of a carbon dioxide laser (112). According to an embodiment the irradiating is performed so as to selectively heat the material layer (102) and a substrate portion (116) of the substrate (104), wherein the substrate portion (116) faces (e.g. contacts) the material layer (102).

A composite silica glass made light diffusion member includes a dense silica glass, and a porous silica glass which has been layered on the surface of the dense silica glass. The porous silica glass is a porous body and has a homogeneous pore distribution. The porous body has a framework including a plurality of spherical silica glasses, contains a communicating pore part formed by spaces among them, and has a central pore size of 10 to 20 μm and a porosity of 25 to 40%. The spherical silica glasses have an average diameter of 30 to 100 μm. An average value of a specific arithmetic average roughness Ra in each of the spherical silica glass exposed on an outer surface of the porous silica glass is 0.8 to 4.0 nm.

In order to achieve both an anti-glare effect and a sparkle-suppressing effect in a transparent article having an anti-glare surface having a recess and protrusion structure, the transparent article has an anti-glare surface having a recess and protrusion structure. The recess and protrusion structure of the anti-glare surface has a 6-20 μm cycle length obtained from the autocorrelation function.

Various embodiments provide an article including a substrate and a coating thereon including a functionalized fluorine containing compound crosslinked with a multifunctional siloxane resin. A method of forming the article includes applying a multifunctional siloxane resin to a substrate, applying a functionalized fluorine containing compound to the substrate, and annealing the multifunctional siloxane resin and the functionalized fluorine containing compound.

A method for preparation of a self-cleaning coating solution is provided. The method comprises mixing an aluminium compound with a solution of an ethanol compound to form a solution. Further, the formed solution is subjected to a first magnetic stirring. After the first magnetic stirring a first transparent solution is formed. Further, a stabilizing agent is added to the first transparent solution of the aluminium compound and the ethanol compound. Subsequent to adding the stabilizing agent a translucent solution is formed. Finally, the formed translucent solution is subjected to a second magnetic stirring for forming a homogeneous second transparent solution. The formed second transparent solution is a coating solution