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77473results about How to "Improve adhesion" patented technology

Field effect transistor

A novel field-effect transistor is provided which employs an amorphous oxide. In an embodiment of the present invention, the transistor comprises an amorphous oxide layer containing electron carrier at a concentration less than 1×10−18 / cm3, and the gate-insulating layer is comprised of a first layer being in contact with the amorphous oxide and a second layer different from the first layer.
Owner:CANON KK +2

Organic electroluminescent display device and manufacturing method thereof

The present invention provides an organic EL display device having a planarizing layer, which is prevented from being distorted. The above organic EL display device has a planarizing layer, which retains 5% or less the oligomer used to form this layer.
Owner:CANON KK

Air permeable pressure-sensitive adhesive tapes

A vapor permeable article includes a porous backing substrate and an open fabric applied to one surface of the backing substrate. The open fabric has a greater porosity than that of the backing substrate. The open fabric may be a woven fabric comprising warp (MD) yarns and weft (CD) yarns, and the warp yarns may be of a lower denier than the weft yarns, so as to facilitate hand-tear of the assembled article. The open fabric is coated with an adhesive in such a manner that the open fabric remains porous and vapor permeable. The backing substrate can be a woven, knit or non-woven fabric, or a porous film, such as an apertured plastic film.
Owner:ANDOVER HEALTHCARE

Coating composition for multiple hydrophilic applications

A coating composition is disclosed which comprises an aqueous polymeric matrix, a hydrophilic polymer, a colloidal metal oxide and a crosslinker. The coating composition when applied on medical devices is hydrophilic, shows improved lubricity, abrasion resistance and substrate adhesion on metallic or plastic substrates. The coating also shows improved water sheeting thus providing the coated substrates with anti-fog properties. The coating absorbs aqueous dye or stain solutions making the substrate suitable for printing.
Owner:HYDROMER INC

Medical device applications of nanostructured surfaces

This invention provides novel nanofiber enhanced surface area substrates and structures comprising such substrates for use in various medical devices, as well as methods and uses for such substrates and medical devices. In one particular embodiment, methods for enhancing cellular functions on a surface of a medical device implant are disclosed which generally comprise providing a medical device implant comprising a plurality of nanofibers (e.g., nanowires) thereon and exposing the medical device implant to cells such as osteoblasts.
Owner:GLO TECH LLC

Fabrication method for a thin film semiconductor device, the thin film semiconductor device itself, liquid crystal display, and electronic device

In order to fabricate a high performance thin film semiconductor device using a low temperature process in which it is possible to use low price glass substrates, a thin film semiconductor device has been fabricated by forming a silicon film at less than 450 DEG C., and, after crystallization, keeping the maximum processing temperature at or below 350 DEG C. In applying the present invention to the fabrication of an active matrix liquid crystal display, it is possible to both easily and reliably fabricate a large, high-quality liquid crystal display. Additionally, in applying the present invention to the fabrication of other electronic circuits as well, it is possible to both easily and reliably fabricate high-quality electronic circuits.
Owner:INTELLECTUAL KEYSTONE TECH

Multilayered material and method of producing the same

A multilayered material is provided which includes a substrate and a silicon-containing film formed on the substrate, wherein the silicon-containing film has a nitrogen-rich area including silicon atoms and nitrogen atoms, or silicon atoms, nitrogen atoms, and an oxygen atoms and the nitrogen-rich area is formed by irradiating a polysilazane film formed on the substrate with an energy beam in an atmosphere not substantially including oxygen or water vapor and denaturing at least a part of the polysilazane film. A method of producing the multilayered material is also provided.
Owner:MITSUI CHEM INC

Method to increase silicon nitride tensile stress using nitrogen plasma in-situ treatment and ex-situ UV cure

Stress of a silicon nitride layer may be enhanced by deposition at higher temperatures. Employing an apparatus that allows heating of a substrate to substantially greater than 400° C. (for example a heater made from ceramic rather than aluminum), the silicon nitride film as-deposited may exhibit enhanced stress allowing for improved performance of the underlying MOS transistor device. In accordance with some embodiments, a deposited silicon nitride film is exposed to curing with plasma and ultraviolet (UV) radiation, thereby helping remove hydrogen from the film and increasing film stress. In accordance with other embodiments, a silicon nitride film is formed utilizing an integrated process employing a number of deposition / curing cycles to preserve integrity of the film at the sharp corner of the underlying raised feature. Adhesion between successive layers may be promoted by inclusion of a post-UV cure plasma treatment in each cycle.
Owner:APPLIED MATERIALS INC

Flowable silicon-carbon-nitrogen layers for semiconductor processing

Methods are described for forming a dielectric layer on a semiconductor substrate. The methods may include providing a silicon-containing precursor and an energized nitrogen-containing precursor to a chemical vapor deposition chamber. The silicon-containing precursor and the energized nitrogen-containing precursor may be reacted in the chemical vapor deposition chamber to deposit a flowable silicon-carbon-nitrogen material on the substrate. The methods may further include treating the flowable silicon-carbon-nitrogen material to form the dielectric layer on the semiconductor substrate.
Owner:APPLIED MATERIALS INC

Cartilage repair plug

A cartilage plug, which is made from a biocompatible, artificial material, that is used to fill a void in natural cartilage that has been resected due to traumatic injury or chronic disease. Alternatively, the plug may be relied upon to anchor a flowable polymer to subchondral bone. The plug is prefabricatable in any size, shape, and contour and may be utilized either singly or in a plurality to fill any size void for any application. The plug may be formed of a laminated structure to match the physiological requirements of the repair site. A plurality of anchoring elements may share a single upper layer.
Owner:ABS

Etch method using a dielectric etch chamber with expanded process window

A method for etching a dielectric in a thermally controlled plasma etch chamber with an expanded processing window. The method is adapted to incorporate benefits of a the thermal control and high evacuation capability of the chamber. Etchent gases include hydrocarbons, oxygen and inert gas. Explanation is provided for enablling the use of hexafluoro-1,3-butadiene in a capacitively coupled etch plasma. The method is very useful for creating via, self aligned contacts, dual damascene, and other dielectric etch.
Owner:APPLIED MATERIALS INC

Compositions with Improved Adhesion to Low Surface Energy Substrates

Acrylic-based pressure sensitive adhesives are modified with a telechelic hydrocarbon oligomer. The oligomer comprises a hydrocarbon polymer chain or backbone and a functional end group, e.g., an oligomer prepared from a mono hydroxyl polybutadiene polymer and toluene diisocyanate. The oligomer attaches to the acrylic backbone of the polymer as a pendant group and in a preferred embodiment, the oligomer is mixed with the PSA shortly before the PSA is coated.
Owner:BRADY WORLDWIDE INC

Coated implantable medical device

A medical device (10) includes a structure (12) adapted for introduction into a patient, the structure (12) being formed of a preferably non-porous base material (14) having a roughened or textured surface (16). The structure (12) is conveniently configured as a vascular stent with a base material (14) of stainless steel, nitinol or another suitable material. The medical device (10) also includes a layer (18) of a bioactive material posited directly upon the roughened or textured surface (16) of the base material (14) of the structure (12). The surface (16) of the base material (14) is roughened or textured by etching or by abrasion with sodium bicarbonate or another suitable grit. A preferred roughened or textured surface (16) is thought to have a mean surface roughness of about 10 μin. (about 250 nm) and a surface roughness range between about 1 μin. and about 100 μin. (about 25 nm and about 2.5 μm). The particularly preferred use of sodium bicarbonate as the abrasive to provide roughness or texture to the surface (16) of the base material (14) of the structure (12) is additionally advantageous in the low toxicity of the sodium bicarbonate to production workers, the ease of product and waste cleanup, and the biocompatibility of any residual sodium bicarbonate.
Owner:COOK MEDICAL TECH LLC

Customizable seal, mask with customizable seal and method of using such a seal

A seal and a mask having a seal adapted for confronting engagement with a surface of a user to form an interface therewith. The seal includes a first portion defined by a gel substance and a second portion associated with the first portion. The second portion includes a selectively formable substance adapted to be molded from a first pattern into a second pattern and to retain the second pattern responsive to being so molded. The seal and mask having the seal is tailored to patient by causing the formable portion of the seal to be placed in a malleable state, applying the seal to the patient while the formable portion is in the malleable state, and causing the formable portion to be placed in a fixed state to retain a shape generally conforming to the portion of the patient underlying the seal.
Owner:RIC INVESTMENTS LLC

Method of forming thin film

A method for forming a thin film includes: supplying an additive gas, a dilution gas, and a silicon-containing source gas into a reaction chamber wherein a substrate is placed; forming a thin film on the substrate by plasma CVD under a given pressure with a given intensity of radio-frequency (RF) power from a first point in time to a second point in time; at the second point in time, stopping the supply of the silicon-containing source gas; and at the second point in time, beginning reducing but not stopping the RF power, and beginning reducing the pressure, wherein the reduction of the RF power and the reduction of the pressure are synchronized up to a third point in time.
Owner:ASM JAPAN

Method to increase silicon nitride tensile stress using nitrogen plasma in-situ treatment and ex-situ UV cure

Stress of a silicon nitride layer may be enhanced by deposition at higher temperatures. Employing an apparatus that allows heating of a substrate to substantially greater than 400° C. (for example a heater made from ceramic rather than aluminum), the silicon nitride film as-deposited may exhibit enhanced stress allowing for improved performance of the underlying MOS transistor device. In accordance with alternative embodiments, a deposited silicon nitride film is exposed to curing with ultraviolet (UV) radiation at an elevated temperature, thereby helping remove hydrogen from the film and increasing film stress. In accordance with still other embodiments, a silicon nitride film is formed utilizing an integrated process employing a number of deposition / curing cycles to preserve integrity of the film at the sharp corner of the underlying raised feature. Adhesion between successive layers may be promoted by inclusion of a post-UV cure plasma treatment in each cycle.
Owner:APPLIED MATERIALS INC
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