Asymmetrically strengthened glass articles, methods for producing the same, and use of the articles in portable electronic device is disclosed. Using a budgeted amount of compressive stress and tensile stress, asymmetric chemical strengthening is optimized for the utility of a glass article. In some aspects, the strengthened glass article can be designed for reduced damage, or damage propagation, when dropped.

An energy-saving glass includes a glass substrate, and a periodic metal layer deposited on the glass substrate and having a honeycomb array of round holes. A method of manufacturing the energy-saving glass includes: providing a template having multiple template spots arranged in a honeycomb array; forming on the template a transfer metal layer having multiple metal spots disposed respectively on the template spots; transferring the metal spots onto a photoresist layer on a glass substrate; etching the photoresist layer exposed from the metal spots to leave photoresist spots underlying the metal spots on the glass substrate; forming a periodic metal layer around the photoresist spots; and removing the photoresist spots.

The present invention relates to a manufacturing method for a camera window and a camera window manufactured thereby. A conventional camera window is configured such that an etching pattern is provided on a back surface of a glass sheet, and a deposition layer is provided on the etching pattern, thereby improving reflectivity, whereby indirect external recognition of the etching pattern is performed, but in the present invention, a distinctive pattern is provided on a front surface of a glass sheet such that direct external recognition of the pattern is possible, whereby it is possible to recognize a distinctive pattern line.

A quartz etching method of the invention includes forming a mask on a quartz glass substrate and carrying out etching using a hydrofluoric acid-based etchant solution. The quartz etching method includes: preparing a quartz glass substrate; forming a mask having a predetermined pattern on the quartz glass substrate; and carrying out etching on the quartz glass substrate. When the quartz glass substrate is prepared, the quartz glass substrate is selected in accordance with a standard such that a concentration of hydroxyl groups included therein is less than or equal to 300 ppm.

The specification discloses a method for containing spills on shelving and the like, and the resulting support members made in accordance with the method, by providing the generally flat top surface of a support with a hydrophobic surface which is arranged in a spill containment pattern and which is generally in the plane of the top surface of the support. The majority of the top surface of the support consists of one or more spill containment areas which are of a non-hydrophobic nature and which are bounded by the hydrophobic surfaces, such that spills on the shelving collect in the non-hydrophobic spill containment area or areas and are prevented from spreading by the hydrophobic surfaces.

The invention relates to a glass substrate for chemical strengthening where a surface is coated by magnetron sputtering with a temporary thin film that reduces the extent of ion exchange upon chemical strengthening and where the temporary thin film can be removed after the chemical strengthening by treatment with an etchant solution. Other embodiments relate to a method for making a chemically strengthened glass substrate with controlled curvature comprising: providing a substrate with opposed surfaces that are durable to a given etchant solution, forming a temporary thin film upon at least part of a surface of the glass substrate, chemically strengthening the glass substrate bearing the temporary thin film, and removing the temporary thin film after said chemical strengthening with said etchant solution. The thickness of the temporary thin film is chosen such that a controlled curvature is obtained upon chemical strengthening.

Solutions suitable for etch cutting glass substrates are disclosed. The solutions can include: (a) about 20.1 to about 25 weight % of hydrofluoric acid; (b) about 7 to about 10.5 weight % of an organic carboxylic acid; (c) 0 to about 10 weight % of nitric acid; and (d) about 54.5 to about 72.9 weight % of water; wherein the weight % is based on the total weight of the etch cutting solution.

Disclosed herein are glass articles and methods of manufacturing the same. The glass articles may include a glass layer comprising a first portion having a first thickness, a second portion having a second thickness, and a third portion disposed in between the first portion and the second portion. The third portion may form a living hinge. The living hinge may comprise a plurality of indentations such that a majority of the third portion has a third thickness that is less than the first thickness and the second thickness. In addition, the living hinge may comprise a plurality of protrusions such that a majority of the third portion has a third thickness that is greater than the first thickness and the second thickness.

A window includes a base substrate including a planar portion and a curved portion surrounding at least a part of the planar portion, a front cover layer disposed on the base substrate, a flat cover layer overlapping the planar portion and disposed on the base substrate, and a bending cover layer overlapping the curved portion and disposed on the base substrate. The front cover layer and the bending cover layer each include an inorganic material.

A system and method for creating an anti-reflective surface structure on an optical device includes a shim including a textured pattern, wherein the ship is configured to stamp the optical device with the textured pattern, a connector configured to place the optical device in proximity to the shim and apply a force to the optical device against the shim, and a laser source configured to heat the optical device by generating and applying a laser beam to the optical device when the optical device is placed in proximity to the shim.