Abstract: Disclosed herein are methods for forming low melting point glass fibers comprising providing a glass feedstock comprising a low melting point glass and melt-spinning the glass feedstock to produce glass fibers, wherein the glass transition temperature of the glass fibers is less than or equal to about 120% of the glass transition temperature of the glass feedstock. The disclosure also relates to method for forming low melting point glass frit further comprising jet-milling the glass fibers. Low melting point glass frit and fibers produced by the methods described above are also disclosed herein.

Abstract: Disclosed herein are methods for forming low melting point glass fibers comprising providing a glass feedstock comprising a low melting point glass and melt-spinning the glass feedstock to produce glass fibers, wherein the glass transition temperature of the glass fibers is less than or equal to about 120% of the glass transition temperature of the glass feedstock. The disclosure also relates to method for forming low melting point glass frit further comprising jet-milling the glass fibers. Low melting point glass frit and fibers produced by the methods described above are also disclosed herein.

Abstract: Disclosed herein are methods for forming low melting point glass fibers comprising providing a glass feedstock comprising a low melting point glass and melt-spinning the glass feedstock to produce glass fibers, wherein the glass transition temperature of the glass fibers is less than or equal to about 120% of the glass transition temperature of the glass feedstock. The disclosure also relates to method for forming low melting point glass frit further comprising jet-milling the glass fibers. Low melting point glass frit and fibers produced by the methods described above are also disclosed herein.

Abstract: A method of forming a sealed device comprising providing a first substrate having a first surface, providing a second substrate adjacent the first substrate, and forming a weld between an interface of the first substrate and the adjacent second substrate, wherein the weld is characterized by ((?tensile stress location)/(?interface laser weld))<<1 or <1 and ?interface laser weld>10 MPa or >1 MPa where ?tensile stress location is the stress present in the first substrate and ?interface laser weld is the stress present at the interface. This method may be used to manufacture a variety of different sealed packages.

Abstract: Disclosed herein are methods for making a sealed device (200), the methods comprising positioning a sealing layer comprising at least one metal between a first glass substrate (201a) and a second substrate (201b) to form a sealing interface; and directing a laser beam operating at a predetermined wavelength onto the sealing interface to form at least one seal (207) between the first and second substrates and to convert the at least one metal to metal nanoparticles. Sealed devices having a seal comprising metal nanoparticles having a particles size of less than about 50 nm are also disclosed herein, as well as display devices comprising such sealed devices.

Abstract: A method of forming a sealed device comprising providing a first substrate having a first surface, providing a second substrate adjacent the first substrate, and forming a weld between an interface of the first substrate and the adjacent second substrate, wherein the weld is characterized by ((?tensile stress location)/(?interface laser weld))<<1 or <1 and ?interface laser weld>10 MPa or >1 MPa where ?tensile stress location is the stress present in the first substrate and ?interface laser weld is the stress present at the interface. This method may be used to manufacture a variety of different sealed packages.

Abstract: A free-standing multi-laminate hermetic sheet includes a first carrier film, a hermetic inorganic thin film formed over the first carrier film, and a second carrier film formed over the hermetic inorganic thin film. A workpiece can be hermetically sealed using the multi-laminate sheet, which can be applied to the workpiece in a step separate from a formation step of either the multi-laminate sheet or the workpiece.

Abstract: Disclosed herein are methods for forming low melting point glass fibers comprising providing a glass feedstock comprising a low melting point glass and melt-spinning the glass feedstock to produce glass fibers, wherein the glass transition temperature of the glass fibers is less than or equal to about 120% of the glass transition temperature of the glass feedstock. The disclosure also relates to method for forming low melting point glass frit further comprising jet-milling the glass fibers. Low melting point glass frit and fibers produced by the methods described above are also disclosed herein.

Abstract: Described herein are glass, ceramic, or glass-ceramic articles having improved antimicrobial efficacy. Further described are methods of making and using the improved articles. The improved articles generally include a glass, ceramic, or glass-ceramic substrate, a compressive stress layer that extends inward from a surface of the glass, ceramic, or glass-ceramic substrate to a first depth therein, and an antimicrobial agent-containing region that extends inward from the surface of the glass, ceramic, or glass-ceramic substrate to a second depth therein.

Abstract: Described herein are glass, ceramic, or glass-ceramic articles having improved antimicrobial efficacy. Further described are methods of making and using the improved articles. The improved articles generally include a glass, ceramic, or glass-ceramic substrate, a compressive stress layer that extends inward from a surface of the glass, ceramic, or glass-ceramic substrate to a first depth therein, and an antimicrobial agent-containing region that extends inward from the surface of the glass, ceramic, or glass-ceramic substrate to a second depth therein.

Abstract: A glass-coated gasket comprises a gasket main body defining an inner hole and having a first contact surface and a second contact surface opposite the first contact surface, and a glass layer formed over at least a portion of one of the first contact surface and the second contact surface. The glass layer comprises a low melting temperature glass. A vacuum insulated glass window comprises a substrate/glass-coated gasket/substrate structure that can be sealed using a thermo-compressive sealing step.

Abstract: A multi-layer thin film laminate comprises a dyad layer including a barrier layer and a decoupling layer formed over a substrate. The barrier layer comprises a hermetic glass material selected from the group consisting of tin fluorophosphate glasses, tungsten-doped tin fluorophosphate glasses, chalcogenide glasses, tellurite glasses, borate glasses and phosphate glasses and the decoupling layer comprises a polymer material.

Abstract: A free-standing multi-laminate hermetic sheet includes a first carrier film, a hermetic inorganic thin film formed over the first carrier film, and a second carrier film formed over the hermetic inorganic thin film A workpiece can be hermetically sealed using the multi-laminate sheet, which can be applied to the workpiece in a step separate from a formation step of either the multi-laminate sheet or the workpiece.

Abstract: A free-standing multi-laminate hermetic sheet includes a first carrier film, a hermetic inorganic thin film formed over the first carrier film, and a second carrier film formed over the hermetic inorganic thin film. A workpiece can be hermetically sealed using the multi-laminate sheet, which can be applied to the workpiece in a step separate from a formation step of either the multi-laminate sheet or the workpiece.

Abstract: A sputtering target comprises a low Tg glass or an oxide of copper or tin. Such target materials can be used to form mechanically-stable thin films that exhibit a self-passivating phenomenon and which can be used to seal sensitive workpieces from exposure to air or moisture. Low Tg glass materials may include phosphate glasses such as tin phosphates and tin fluorophosphates, borate glasses, tellurite glasses and chalcogenide glasses, as well as combinations thereof.

Abstract: A glass-coated gasket comprises a gasket main body defining an inner hole and having a first contact surface and a second contact surface opposite the first contact surface, and a glass layer formed over at least a portion of one of the first contact surface and the second contact surface. The glass layer comprises a low melting temperature glass. A hermetic package comprises a substrate/glass-coated gasket/substrate structure that can be sealed using a thermo-compressive sealing step.

Abstract: A method for hermetically sealing a device without performing a heat treatment step and the resulting hermetically sealed device are described herein. The method includes the steps of: (1) positioning the un-encapsulated device in a desired location with respect to a deposition device; and (2) using the deposition device to deposit a sealing material over at least a portion of the un-encapsulated device to form a hermetically sealed device without having to perform a post-deposition heat treating step. For instance, the sealing material can be a Sn2+-containing inorganic oxide material or a low liquidus temperature inorganic material.

Abstract: A substrate having a durable hydrophobic and/or oleophobic surface. The durable hydrophobic and/or oleophobic surface includes a first layer that is disposed on the substrate and comprises inorganic nanoparticles, an outer layer comprising a fluorosilane, and an optional immobilizing layer that comprises at least one of an inorganic oxide and a silsesquioxane. The durable surface is capable of retaining optical properties, such as haze, and hydrophobic and/or oleophobic properties after repeated contact with foreign objects such as, for example, wiping with a cloth or human finger.

Abstract: A free-standing multi-laminate hermetic sheet includes a first carrier film, a hermetic inorganic thin film formed over the first carrier film, and a second carrier film formed over the hermetic inorganic thin film. A workpiece can be hermetically sealed using the multi-laminate sheet, which can be applied to the workpiece in a step separate from a formation step of either the multi-laminate sheet or the workpiece.

Abstract: Described herein are alkali-free, boroalumino silicate glasses exhibiting desirable physical and chemical properties for use as substrates in flat panel display devices, such as, active matrix liquid crystal displays (AMLCDs). The glass compositions possess numerous properties that are compatible with the downdraw process, particularly fusion drawing.