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 of the shortest distance from the edge to the center point.

A solid state electrolyte including an oxy-sulfide glass or glass ceramic, solid state electrolyte layer having a thickness in the range of ten micrometers to two hundred micrometers is provide. The composition of the electrolyte layer is the reaction product of a mixture initially including either a glass former including sulfur or a glass co-former including sulfur, and a glass modifier including Li.sub.2O or Na.sub.2O. The solid-state electrolyte layer is further characterized as having a wholly amorphous microstructure or as having small recrystallized regions separated from each other in an amorphous matrix, the recrystallized regions having a size of up to five micrometers. The solid-state electrolyte layer includes mobile lithium ions or mobile sodium ions associated with sulfur anions chemically anchored in the microstructure.

An apparatus includes a fiber feeding system to deposit a fiber on an edge of the glass article and a laser system. The laser system is positioned to project a first and a second laser beam onto a first and a second side of the fiber, respectively. The laser system is positioned to project a third laser beam onto the edge of the glass article. A method includes advancing a glass article relative to a fiber; positioning the fiber in relation to an edge of the glass article, contacting a first side of the fiber with a first laser beam, contacting a second side of the fiber with a second laser beam, depositing the fiber on the edge of the glass article, and contacting the edge of the glass article with a third laser beam.

A method includes the steps of: providing a mold substrate and a cover substrate that are bonded to each other, wherein a surface region of the mold substrate and/or of the cover substrate is structured so as to form an enclosed cavity between the cover substrate and the mold substrate; tempering the cover substrate and the mold substrate so as to decrease the viscosity of the glass material of the cover substrate, and providing an overpressure in the enclosed cavity compared to the surrounding atmosphere so as to cause, on the basis of the decreased viscosity of the glass material of the cover substrate and the overpressure in the enclosed cavity compared to the surrounding atmosphere, bulging of the glass material of the cover substrate starting from the enclosed cavity up to a stop area, spaced apart from the cover substrate, of a stop element so as to acquire a molded cover substrate with a cap element; and removing the stop element and the mold substrate from the molded cover substrate.

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 of the shortest distance from the edge to the center point.

Foldable apparatus comprise a foldable substrate comprising a substrate thickness. The second major surface of the foldable substrate faces an end portion of a first inner surface area of a first housing member extending along a first plane. The second surface faces an end portion of a second inner surface area of a second housing member extending along a second plane. A support is attached to at least the second housing member. The support contacts the second major surface when an angle between the first plane and the second plane ranges from about 80? to about 135?. The support is spaced from the second major surface when an angle between the first plane and the second plane ranges from about 0? to about 30?. In some embodiments, the foldable substrate comprises a neutral stress configuration at a parallel plate distance ranging from about 20 millimeters to about 200 millimeters.

A sheet of glass can be formed in a batch process by introducing molten glass onto a layer of molten tin within a tank. The tank may be outfitted with infrared emitters to control the amount of heat delivered to the tank while the sheet of glass is formed. A lower surface of the tank can have a three-dimensional shape, and the molten tin may be removed from the tank while the sheet of glass is ductile so that the sheet of glass is molded by the three-dimensional shape, thereby producing a shaped sheet of glass. The delivery of infrared energy to the tank may be facilitated by one or more ceramic glass surface.

A glass article including a first main surface, a second main surface, and an end face, in which: the glass article includes an antiglare layer on the first main surface side; the antiglare layer has a glass transition point Tg of equal to or less than a glass transition point Tg.sub.0 of the glass article at a center portion in a cross section along a thickness direction; and the first main surface has a protrusion diameter y (m) that satisfies the relation (1) with respect to a 60 specular gloss (gloss value) x (%) of the first main surface,

y>0.0245x+3.65(1).

A manufacturing method of a glass panel for a glass panel unit includes a melting step, a spreading step, an annealing step, a cutting step, and a spacer disposition step. The spacer disposition step is a step of disposing spacers onto a glass sheet and is performed by a spacer disposition device prior to the cutting step.

A device for producing and removing an internal contour from a planar substrate comprising: a beam-producing- and beam-forming arrangement which is configured to perform: a contour definition step wherein a laser beam is guided over the substrate to produce a plurality of individual zones of internal damage in a substrate material along a contour line defining the internal contour; a crack deformation step, wherein the laser beam is guided over the substrate and produces a plurality of individual zones of internal damage in the substrate material to form a plurality of crack line portions that lead away from the contour line into the internal contour; and a material removal-step, wherein a laser beam directed towards the substrate surface that inscribes a removal line through a thickness of the substrate at the internal contour causes the internal contour to detach from the substrate.