A sulfide solid electrolyte for use in an all-solid-state battery has a composition represented by (100x) [yLi.sub.2S.Math.(1y)P.sub.2S.sub.5].Math.xLiBH.sub.4. In the formula, x is a value satisfying 50<x<75, and y is a value satisfying 0.72y0.78. The sulfide solid electrolyte has an ionic conductivity of 5.0 mS/cm or more at 25 C.

Systems and methods for remediating streak in glass ribbons formed from glass forming processes are disclosed. The systems include a laser that produces a stationary laser beam having a wavelength of from about 1 m to about 12 m and a beam width less than or equal to a full width half maximum of a change in the thickness of the glass ribbon over a streak width at a streak location and optical components to condition and direct the laser beam at the streak location. The methods include forming the glass ribbon, identifying a streak in the glass ribbon, and directing the laser beam at the streak location. The laser beam heats the glass ribbon at the location of the streak, which reduces a viscosity of the glass ribbon to cause glass thinning that reduces the severity of the streak.

Systems and methods for remediating streak in glass ribbons formed from glass forming processes are disclosed. The systems include a laser that produces a stationary laser beam having a wavelength of from about 1 m to about 12 m and a beam width less than or equal to a full width half maximum of a change in the thickness of the glass ribbon over a streak width at a streak location and optical components to condition and direct the laser beam at the streak location. The methods include forming the glass ribbon, identifying a streak in the glass ribbon, and directing the laser beam at the streak location. The laser beam heats the glass ribbon at the location of the streak, which reduces a viscosity of the glass ribbon to cause glass thinning that reduces the severity of the streak.

Latent colorant material compositions, soda-lime-silica glass compositions, and related methods of manufacturing color-strikable glass containers. The latent colorant material compositions may be introduced into a plurality of base glass compositions having redox numbers in the range of 40 to +20 to produce color-strikable glass compositions and color-strikable glass containers. The latent colorant material compositions introduced into the base glass compositions include a mixture of cuprous oxide (Cu.sub.2O), stannous oxide (SnO), bismuth oxide (Bi.sub.2O.sub.3), and carbon (C). After formation, the color-strikable glass containers may be heat-treated to strike red or black therein.

Latent colorant material compositions, soda-lime-silica glass compositions, and related methods of manufacturing color-strikable glass containers. The latent colorant material compositions may be introduced into a plurality of base glass compositions having redox numbers in the range of 40 to +20 to produce color-strikable glass compositions and color-strikable glass containers. The latent colorant material compositions introduced into the base glass compositions include a mixture of cuprous oxide (Cu.sub.2O), stannous oxide (SnO), bismuth oxide (Bi.sub.2O.sub.3), and carbon (C). After formation, the color-strikable glass containers may be heat-treated to strike red or black therein.

A process and an apparatus for imparting coloration to a glass container having a strikable glass container composition. One or more portions of the glass container are selectively and locally exposed to a temperature at or above a glass container striking temperature to affect a color change in the one or more portions of the glass container. The coloration process may be carried out by passing the glass container through an interior of an apparatus having a heating system configured to locally heat a first region within the interior to a temperature at or above a glass container striking temperature and a cooling system to locally cool a second region within the interior to a temperature below the glass container striking temperature.

A process and an apparatus for imparting coloration to a glass container having a strikable glass container composition. One or more portions of the glass container are selectively and locally exposed to a temperature at or above a glass container striking temperature to affect a color change in the one or more portions of the glass container. The coloration process may be carried out by passing the glass container through an interior of an apparatus having a heating system configured to locally heat a first region within the interior to a temperature at or above a glass container striking temperature and a cooling system to locally cool a second region within the interior to a temperature below the glass container striking temperature.

A method of making a strengthened glass article. The method includes altering the glass structure and subsequently creating a compressive layer extending from the surface of the glass to a depth of layer. In some embodiments, the structure is altered by heat treating the glass at a temperature that is less than the annealing point of the glass, and the compressive layer is formed by ion exchange. A strengthened glass article made by the method is also provided.

A method of making a strengthened glass article. The method includes altering the glass structure and subsequently creating a compressive layer extending from the surface of the glass to a depth of layer. In some embodiments, the structure is altered by heat treating the glass at a temperature that is less than the annealing point of the glass, and the compressive layer is formed by ion exchange. A strengthened glass article made by the method is also provided.

The present invention relates to a decorative ceramic or vitreous sink customized with unique designs, themes, logos, pictures, stamps, etc and the manufacturing method of the same. The decorative ceramic or vitreous sink can be used as a personalized fixture in home or as a medium for advertisement and commercialization by way of descriptive images and logos imprinted on the surface of the sink. The material is heated at 200 F. for two hours first, then at 300 F. for two hours and finally at 300 to 400 F. for two hours.