Abstract: An optical fiber having both low macrobend loss and low microbend loss. The fiber has a central core region, a first (inner) cladding region surrounding the central core region and having an outer radius r2>16 microns and relative refractive index ?2, and a second (outer) cladding region surrounding the first cladding region having relative refractive index, ?3, wherein ?1>?3>?2. The difference between ?3 and ?2 is greater than 0.12 percent. The fiber exhibits a 22 m cable cutoff less than or equal to 1260 nm, and r1/r2 is greater or equal to 0.24 and bend loss at 1550 nm for a 15 mm diameter mandrel of less than 0.5 dB/turn.

Abstract: A method of controllably bonding a thin sheet having a thin sheet bonding surface with a carrier having a carrier bonding surface, by depositing a carbonaceous surface modification layer onto at least one of the thin sheet bonding surface and the carrier bonding surface, incorporating polar groups with the surface modification layer, and then bonding the thin sheet bonding surface to the carrier bonding surface via the surface modification layer. The surface modification layer may include a bulk carbonaceous layer having a first polar group concentration and a surface layer having a second polar group concentration, wherein the second polar group concentration is higher than the first polar group concentration. The surface modification layer deposition and the treatment thereof may be performed by plasma polymerization techniques.

Abstract: A method for scale-up of a micro reactor process from lab to production scale comprises using a wall material for a lab reactor having thermal conductivity ?3 W/m·K, and using a wall material for a production reactor having thermal conductivity ?5 W/m·K. Desirably, flow velocity is kept constant, and the height of the production-scale process channel is determined by: H G = 2 × ( A + B ? W + 1 C × ( D h ) ( b - 1 ) ) - 1 h = H G ? ? 0 wherein A B and C are constants; HG is the overall volumetric heat transfer coefficient, Dh is the hydraulic diameter, ?W is the thermal conductivity of the wall, b is the empirically determined power to which the Reynolds number is raised in the equation for the Nusselt criteria (Nu=a·RebPrc) for the type of flow used, and h is the height of the channel, all in the production-scale process; and HG0 is the overall volumetric heat transfer coefficient in the lab-scale process.

Abstract: Embodiments are directed to systems for laser cutting at least one glass article comprising a pulsed laser assembly and a glass support assembly configured to support the glass article during laser cutting within the pulsed laser assembly, wherein the pulsed laser assembly comprises at least one non-diffracting beam (NDB) forming optical element configured to convert an input beam into a quasi-NDB beam; and at least one beam transforming element configured to convert the quasi-NDB beam into multiple quasi-NDB sub-beams spaced apart a distance of about 1 ?m to about 500 ?m; wherein the pulsed laser assembly is oriented to deliver one or more pulses of multiple quasi-NDB sub-beams onto a surface of the glass article, wherein each pulse of multiple quasi-NDB sub-beams is operable to cut a plurality of perforations in the glass article.

Abstract: A plate-type flow reactor device with a first plate (20) having first and second opposing surfaces (22, 24) and one or more through-holes (26); a second plate sealed against the first surface (22) by at least two first O-rings (50); a third plate (40) sealed against the second surface (24) by at least one second O-ring (60); two or more first elongated channels (70) defined between the first surface (22) and the second plate and one or more second elongated channels (80) defined between the second surface (24) and the third plate, wherein each first channel communicates with the at least one second channel (80) via one or more of the through-holes (26) through the first plate (20), and said one first channel (70a) communicates with another first channel (70b) of the two or more first channels (70) only via said at least one second channel (80), and each first channel (70) is individually surrounded by at least one of the first O-rings (50) and the at least one second is individually surrounded by the at least

Abstract: The present invention discloses cryopreserved recombinant cells for screening drug candidates that transiently overexpress one or more drug transporter proteins and/or drug metabolizing enzymes. Advantageously, such cells provide a cost-efficient consumable product that streamlines the process of screening whether drug candidates are substrates or inhibitors of drug transporter proteins and/or drug metabolizing enzymes.

Abstract: A cover glass article includes a glass body having a three-dimensional shape, an inside surface, and an outside surface. Each of the inside and outside surfaces has a surface roughness (Ra) less than 1 nm and is free of indentations having diameters larger than 150 ?m.

Abstract: A non-extruded filter article, including: an activated carbon honeycomb substrate having a plurality of flow-through channels and porous walls, and the activated carbon substrate comprises a carbon in from 90 to 99.9 wt. % of the article, and the porous walls have a percentage porosity of from 40% to 65%. Also disclosed is a non-extrusion method of making the article and a method of using the article.

Abstract: Methods of modifying glass-ceramic articles and glass-ceramic articles formed therefrom. The methods include providing a glass-ceramic article having a non-damaged surface, applying a chemical etching solution to the non-damaged surface, and removing the chemical etching solution. The chemical etching solution modifies the non-damaged surface so that from about 0.01 ?m to about 2 ?m of a depth of the glass-ceramic article is removed. The chemical etching solution modifies the non-damage surface of the glass-ceramic article to form a roughened surface having a reduced gloss value and a target roughness value.

Abstract: A fining agent for reducing the concentration of seeds or bubbles in a silicate glass. The fining agent includes at least one inorganic compound, such as a hydrate or a hydroxide that acts as a source of water. In one embodiment, the fining agent further includes at least one multivalent metal oxide and, optionally, an oxidizer. A fusion formable and ion exchangeable silicate glass having a seed concentration of less than about 1 seed/cm3 is also provided. Methods of reducing the seed concentration of a silicate glass, and a method of making a silicate glass having a seed concentration of less than about 1 seed/cm3 are also described.

Abstract: Embodiments of this disclosure pertain to a laminate including a first substrate, an interlayer and a light responsive material disposed on the first substrate, and a second substrate disposed on the interlayer. The laminate may be complexly curved. The light responsive material may include any one or more of an electrochromic material, a photochromic material, a suspended particle material, a micro-blind material and a liquid crystal material. In one or more embodiments, the laminate comprises a display unit disposed between the first and second substrate. Methods for forming the laminate are also disclosed.

Abstract: A glass laminate comprises an external glass sheet, an internal glass sheet, and a polymer interlayer formed between the external glass sheet and the internal glass sheet. The external glass sheet can be a thin chemically-strengthened glass sheet or can be a non-chemically strengthened glass sheet, the polymer interlayer can have a thickness of less than 1.6 mm, and the internal glass sheet can be a non-chemically-strengthened glass sheet or a thin chemically strengthened glass sheet.

Abstract: A pharmaceutical package may include a glass body enclosing an inner volume and having an exterior surface. The glass body may be formed from a borosilicate glass that meets the Type 1 criteria according to USP <660>or an alkali aluminosilicate glass having a Class HGA 1 hydrolytic resistance when tested according to the ISO 720-1985 testing standard. A coupling agent layer having a first thickness less than or equal to 100 nm may be disposed on the exterior surface of the glass body. A polymer layer having a second thickness of less than 50 nm may be positioned over the coupling agent layer. The exterior surface of the glass body with the coupling agent layer and the polymer layer may have a coefficient of friction less than or equal to 0.7.

Abstract: One embodiment of the disclosure relates to a fiber coating apparatus having a fiber entrance opening, a conical section with walls tapered at half angles between 2 and 25° and height (also referred to as length herein) L1 between 0.25 mm and 2 mm, and a cylindrical land portion of diameter d2 between 0.1 and 0.5 mm and height (length) L2 between 0.05 and 1.25 mm.

Abstract: A glass laminate comprises an external glass sheet, an internal glass sheet, and a polymer interlayer formed between the external glass sheet and the internal glass sheet. The external glass sheet is a chemically-strengthened glass sheet having a thickness of less than 1 mm, the polymer interlayer has a thickness of less than 1.6 mm, and the internal glass sheet is a non-chemically-strengthened glass sheet having a thickness of less than 2.5 mm.

Abstract: Methods of manufacturing a glass pane comprise the steps of providing a glass sheet with a thickness of less than about 1.6 mm between a first major surface and a second major surface of the glass sheet. The methods include scoring the first major surface of the glass sheet to provide a boundary score line and a relief score line. In some examples, the method provides a relief score depth that is greater than a boundary score depth. In another example, the method includes the step of placing the glass sheet on a conveyor belt including a Shore A hardness of greater than or equal to 70. In further examples, methods of breaking a glass sheet with an oversized template are provided.

Abstract: A material system for a surface display unit that includes a first side (i.e., a proximal side) that faces a viewer of the surface display unit and a second side (i.e., a distal side) facing away from the viewer. The material system provides at least three appearance states, including a generally opaque first appearance state when the surface display unit is “off” (i.e., not used to display images), a second appearance state in which the material system is illuminated from the first (i.e., proximal) side to display a first image (e.g., information and/or decoration) that is perceptible to the viewer, and a third appearance state in which the material system is illuminated from the second (i.e., distal) side to display a second image (e.g., information and/or decoration) that is perceptible to the viewer. Surface display units, systems, and methods comprising the material system are also disclosed.

Abstract: Methods for making a ceramic or glass-ceramic include spray-drying a mixture comprising batch materials to form agglomerated particles; bringing the agglomerated particles into contact with a plasma for a residence time sufficient to form fused particles; and annealing the fused particles at a temperature and for a time sufficient to form ceramic or glass-ceramic particles. The methods can be used to produce fused glass particles, ceramic or glass-ceramic particles, and ceramic or glass-ceramic articles, such as ceramic honeycombs.

Abstract: An apparatus for downwardly drawing glass ribbon comprises edge directors, wherein an outer portion defining a first pair of surfaces and a second pair of surfaces. In one example, the first and second pair of surfaces of each edge director includes a glass wettability with a static contact angle within a range of from about 30° to about 60°. In another example, the outer portion comprises a platinum alloy including from about 0.05 weight % tin to about 5 weight % tin. Methods for forming glass include the step of providing the edge director with a desired glass wettability and/or a desired platinum alloy.

Abstract: Described herein is a substrate including a central longitudinal axis, a first support web, and a second support web. A sinuous web may be positioned between the first support web and the second support web. The sinuous web may include transverse web portions and bridging web portions, where the bridging web portions alternatively connect ends of adjacent transverse web portions. The sinuous web may be connected to the first support web by support legs extending between bridging web portions and a surface of the first support web. The sinuous web may be connected to the second support web by support legs extending between bridging web portions and a surface of the second support web. A support leg length to distance between transverse web portions ratio may be from about 1.0 to about 4.0.