Methods for increasing the hydrolytic resistance of a glass article are disclosed. According to one embodiment, the method includes providing a glass article with a pre-treatment hydrolytic titration value. Thereafter, the glass article is thermally treated at a treatment temperature greater than a temperature 200C less than a strain temperature of the glass article for a treatment time greater than or equal to about 0.25 hours such that, after thermally treating the glass article, the glass article has a post-treatment hydrolytic titration value that is less than the pre-treatment hydrolytic titration value.

Disclosed herein are glass-based articles having a first surface having an edge, wherein a maximum optical retardation of the first surface is at the edge and the maximum optical retardation is less than or equal to about 40 nm and wherein the optical retardation decreases from the edge toward a central region of the first surface, the central region having a boundary defined by a distance from the edge toward a center point of the first surface, wherein the distance is ½ of the shortest distance from the edge to the center point.

A curved glass manufacturing method includes: successively stacking a lower mold, flat glass, and an upper mold, thereby forming a mold assembly; moving the mold assembly to a first chamber and then heating the same; moving the mold assembly from the first chamber to a second chamber and then pressurizing the upper mold so as to move the upper mold downward, thereby molding the flat glass in a curved shape; moving the mold assembly from the second chamber to a third chamber and then slowly cooling the molded glass; and moving the mold assembly from the third chamber to a fourth chamber and then cooling the molded glass. An elastic member is arranged between the lower mold and the upper mold and configured to define a space between the upper mold and the flat glass, and the elastic member is compressed when the upper mold is pressurized.

A technical object of the present invention is to devise a glass sheet that is suitable for supporting a substrate to be processed to be subjected to high-density wiring and has high end surface strength, and a method of manufacturing the glass sheet, to thereby contribute to an increase in density of a semiconductor package. The glass sheet of the present invention has a total thickness variation of less than 2.0 μm, all or part of an end surface of the glass sheet including a melt-solidified surface.

Disclosed herein are systems for shaping glass structures, comprising a shaping mold; a magnetic field generator; and a susceptor plate positioned substantially between the shaping mold and the magnetic field generator. Also disclosed herein are systems for shaping a glass structures, comprising a magnetic field generator comprising at least one induction coil and a one power supply connected to the at least one induction coil; and a susceptor plate having a first surface proximate the at least one induction coil and an opposing second surface proximate the glass structure. Further disclosed herein are methods for heating glass structures, comprising positioning the glass structure on a shaping mold; introducing the shaping mold and glass structure into a furnace; and indirectly heating at least a portion of the glass structure using at least one induction heating source.

Methods for producing glass articles from laminated glass tubing include introducing the glass tubing to a converter. The glass tubing includes a core layer under tensile stress, an outer clad layer under, and an inner clad layer. The methods include forming a feature the glass article at a working end of the laminated glass tubing and separating a glass article from the working end of the laminated glass tubing, which may expose the core layer under tensile stress at the working end of the glass tubing. The method further comprises remediating the exposed portion of the core layer by completely enclosing the core layer in a clad layer. Systems for re-cladding the exposed portion of the core layer as well as glass articles made using the systems and methods are also disclosed.

Methods for increasing the strength of a planar or strip-shaped glass substrate are provided. Electromagnetic radiation in the wavelength range from 180 nm to 1100 nm is applied to the glass substrate by means of at least one pulse, wherein the at least one pulse has a radiation bandwidth of at least 100 nm and the glass substrate has a temperature of at most 200° C. prior to the at least one pulse acting thereon, and wherein the pulse energy density of the at least one pulse of electromagnetic radiation is set in the range from 0.1 Jcm-2 to 100 Jcm-2.

A method of making a glass sheet comprises laminating a high CTE core glass to a low CTE clad glass at high temperatures and allowing the laminate to cool creating compressive stress in the clad glass, and then ion exchanging the laminate to increase the compressive stress in the outer near surface regions of the clad glass. The core glass may include ions that exchange with ion in the clad glass to increase the compressive stress in inner surface regions of the clad glass adjacent to the clad glass/core glass interfaces. The glass laminate may be formed and laminated using a fusion forming and laminating process and fusion formable and ion exchangeable glass compositions.

A glass package includes a glass body with a rim at least partially circumscribing a cavity and a glass lid with a peripheral portion bonded to the rim and a central portion overlying the cavity. A bond between the lid and the body includes interior and exterior perimeter bonds and a filler bond disposed at least partially between the interior and exterior perimeter bonds. The filler bond includes Sa plurality of first bond paths that are substantially parallel to each other and a plurality of second bond paths that are substantially parallel to each other. The plurality of first bond paths and the plurality of second bond paths intersect each other to form a grid pattern.

A method for manufacturing an annular glass plate that has an outer circumferential edge surface, an inner circumferential edge surface, and a thickness not larger than 0.6 mm includes processing for manufacturing an annular glass plate by irradiating each of the outer circumferential edge surface and the inner circumferential edge surface of an annular glass blank with a laser beam to melt the outer circumferential edge surface and the inner circumferential edge surface and form molten surfaces such that the molten surfaces in the outer circumferential edge surface and the inner circumferential edge surface each have an arithmetic average surface roughness Ra not larger than 0.1 μm, and the surface roughness of the molten surface in the inner circumferential edge surface becomes larger than the surface roughness of the molten surface in the outer circumferential edge surface.