A coated glass element includes: a glass surface; and a coating that coats at least part of the glass surface. The coating includes at least one layer. The at least one layer of the coating fulfills the following parameter: [Si.sub.2C.sub.5H.sub.15O.sub.2.sup.−].sub.20/[Si.sub.2C.sub.5H.sub.15O.sub.2.sup.−].sub.80≥1.0. [Si.sub.2C.sub.5H.sub.15O.sub.2.sup.−].sub.20 are counts of [Si.sub.2C.sub.5H.sub.15O.sub.2] ions, measured by a time-of-flight secondary ion mass spectrometry (TOF-SIMS), at 20% of a time a sputter gun beam needs to reach the glass surface and [Si.sub.2C.sub.5H.sub.15O.sub.2.sup.−].sub.80 are counts of [Si.sub.2C.sub.5H.sub.15O.sub.2.sup.−].sub.80 ions, measured by a TOF-SIMS, at 80% of a time a sputter gun beam needs to reach the glass surface.

A coated glass element includes: a glass surface and a coating that coats at least part of the glass surface. The coating has at least one layer. The at least one layer of the coating fulfills the following parameter: [Al.sup.+].sub.80/[Al.sup.+].sub.20≥1.8. [Al.sup.+].sub.20 are counts of [Al.sup.+] ions, measured by a time-of-flight secondary ion mass spectrometry (TOF-SIMS), at 20% of a time a sputter gun beam needs to reach the glass surface and [Al.sup.+].sub.80 are counts of [Al.sup.+] ions, measured by a TOF-SIMS, at 80% of a time a sputter gun beam needs to reach the glass surface.

One or more aspects of the disclosure pertain to an article including a film disposed on a glass substrate, which may be strengthened, where the interface between the film and the glass substrate is modified, such that the article has an improved average flexural strength, and the film retains key functional properties for its application. Some key functional properties of the film include optical, electrical and/or mechanical properties. In one or more embodiments, the interface exhibits an effective adhesion energy of about less than about 4 J/m.sup.2. In some embodiments, the interface is modified by the inclusion of a crack mitigating layer containing an inorganic material between the glass substrate and the film.

Provided are a glass substrate with a metal or ceramic coating formed, where a base film for enhancing the adhesion between the base surface of the glass substrate and the coating is provided in the region with the coating formed, and a glass part obtained by further forming a coating of a metal or a ceramic on the glass substrate.

A super-hydrophobic film layer, a preparation method thereof, and a product thereof are provided, the preparation method includes using a siloxane monomer as a reaction material to form a super-hydrophobic film layer on a surface of a substrate by a plasma enhanced chemical vapor deposition.

The present disclosure is directed to a vessel having a lumen defined at least in part by a wall, the wall having an interior surface facing the lumen, and the interior surface comprising a coating. The coating is configured to prevent the leaching of metal ions from the vessel wall into a fluid contained within the lumen and stored in contact with the coating. The vessels are used to store an aqueous drug product, typically an aqueous drug product containing an active agent and one or more excepients, such as a polysorbate stabilizer. The coated vessels are effective to reduce degradation of the active agent and/or one or more excipients, e.g. a polysorbate stabilizer.

The present invention relates to a laminate including: a support substrate; and a laminated portion, including an adhesion layer, a polyimide layer, and an inorganic layer, disposed on the support substrate, in which, when the laminate is observed from a normal direction of its surface, an outer edge of the polyimide layer is located outside an outer edge of the adhesion layer, and an outer edge of the inorganic layer coincides with the outer edge of the adhesion layer; the outer edge of the inorganic layer is located inside the outer edge of the adhesion layer; or a part of the outer edge of the inorganic layer coincides with a part of the outer edge of the adhesion layer and a remaining part of the outer edge of the inorganic layer is located inside the outer edge of the adhesion layer.

The present invention relates to: a method of manufacturing glass with hollow nanopillars, which includes a silicon oxide layer forming step in which a silicon oxide layer made of silicon oxide is formed on one side of a glass substrate, a first etching step in which the silicon oxide layer is etched and a plurality of silicon oxide clusters are formed on the glass substrate, and a second etching step in which the glass substrate, on which the silicon oxide clusters are formed, is etched and hollow nanopillars are formed; and glass with hollow nanopillars manufactured thereby.

Substrate with transparent outer layer, wherein a transparent interdigital structure is disposed between the substrate and the outer layer.

The invention relates to a glass substrate including a stack of coating layers having control properties, in which stack comprises at least one niobium metal layer located between a layer of a dielectric material selected from Si.sub.3N.sub.4 or TiOx and a layer of a protective metal material selected from TIN or Ni—Cr, conferring solar control and heat resistance properties on the glass substrate.