Abstract: An electronic system (1) having an interconnect structure (30, 45). In one embodiment a system (1) includes a first electronic device (2) with a first plurality of contact pads (15) each having a noble metal (18) formed along a first surface (19), and a second electronic device (3) with a second plurality of contact pads (29) each having a noble metal (18) formed along a first surface (19). The noble metal (18) of one of the contact pads (15) of the first device (2) is bonded to the noble metal (18) of one of the contact pads (29) of the second device (3). In one embodiment of an associated method of forming an interconnect structure (45), a first electronic device (2) is provided with a first plurality of contact pads (15) each having a noble metal (18) along a first surface (19), and a second electronic device (3) is provided with a plurality of contact pads (29) each having a noble metal (18) along a first surface (19).

Abstract: Disclosed is an optical device structure comprising a low shrinkage mixture wherein the shrinkage of the mixture is limited after the curing of the mixture during optical device formation. Disclosed also are methods for forming optical devices which comprise the low shrinkage mixture.

Abstract: A base composition is provided. The base composition includes a binder, a reactive monomer, and an anti-haze additive. The binder may include an optically transmissive polymer. The reactive monomer may be both curable and volatile. The binder and the reactive monomer have differing refractive indices relative to each other. A cured layer formed from the base composition may be formed into an article have particular properties. A method of making the layer is provided.

Abstract: A method for manufacturing an embossed surface including a polymer composition having reactive moieties and a first glass transition temperature Tg1. The method includes embossing the surface a temperature Temb; and raising the first glass transition temperature Tg1 of the embossed polymeric surface to a second glass transition temperature Tg2 such that Tg2>Temb. In another embodiment, a method for improving the release of a polymeric surface from an embossing tool includes incorporating one or more of fluorine atoms, silicon atoms, or siloxane segments into the backbone of polymer. The methods are particular suited for direct patterning of photoresists, fabrication of interdigitated electrodes, and fabrication of data storage media.

Abstract: A microfluidic system and method for its fabrication is disclosed comprising an interposed intermediate layer covering the channel-containing layers, said intermediate layers comprising an integral valve made from the intermediate layer material. A microfluidic system and method is also disclosed for actively pumping a fluid through an integrated layered device incorporating the above-mentioned channels, valves in communication with a chamber, the volume of which can be predictably controlled by interaction between a magnetizable assembly placed on pre-selected sides of the chamber.

Abstract: An optical device structure includes a first cladding having a first refractive index, a second cladding having a second refractive index, a core disposed between the first and second claddings, wherein the core has a third refractive index, and wherein the first and second refractive indices are relatively lower than the third refractive index, and a diffusion region disposed between the core and one of the first cladding, the second cladding, or both. A method for making the aforementioned optical device structure is provided.

Abstract: A composite article with at least one high integrity protective coating, the high integrity protective coating having at least one planarizing layer and at least one organic-inorganic composition barrier coating layer. A method for depositing a high integrity protective coating.

Abstract: A method of forming a waveguide including a core region, a cladding region, and an index contrast region situated therebetween includes depositing a polymerizable composite on a substrate to form a layer, patterning the layer to define an exposed area and an unexposed area of the layer, irradiating the exposed area of the layer, and volatilizing the uncured monomer to form the waveguide, wherein the polymerizable composite includes a polymer binder and sufficient quantities of an uncured monomer to diffuse into the exposed area of the layer and form the index contrast region. The resulting waveguide includes an index contrast region which has a lower index of refraction than that of the core and cladding regions.

Abstract: A method of forming a waveguide including a core region, a cladding region, and an index contrast region situated therebetween includes depositing a polymerizable composite on a substrate to form a layer, patterning the layer to define an exposed area and an unexposed area of the layer, irradiating the exposed area of the layer, and volatilizing the uncured monomer to form the waveguide, wherein the polymerizable composite includes a polymer binder and sufficient quantities of an uncured monomer to diffuse into the exposed area of the layer and form the index contrast region. The resulting waveguide includes an index contrast region which has a lower index of refraction than that of the core and cladding regions.

Abstract: A method of fabricating a stamping mold suitable for use in the formation of a tapered waveguide structure includes defining a stamping pattern upon the surface of a silicon wafer, and removing portions of the silicon wafer surface in accordance with the stamped pattern, thereby creating tapered vertical surfaces within the wafer.

Abstract: A method for applying a protective coating to the inner surface of the arc tube of a high-intensity metal halide discharge lamp involves dosing the arc tube with an inert gas that is doped with a metal hydride gas. Preferably, the metal hydride gas comprises silane. The arc tube is heated to a sufficiently high temperature to decompose the silane gas. As a result, silicon is deposited as a protective coating on the inner surface of the arc tube wall. The hydrogen gas that is generated by the silane decomposition is removed from the system either by pumping it out before dosing the arc tube with the final arc tube fill, or by diffusion through the arc tube wall during operation of the lamp.