The present invention relates to a coated substrate comprising a substrate surface coated with a coating comprising at least one layer, wherein the at least one layer comprises titanium, aluminum and nitrogen, wherein—the content of aluminum in relation to the content of titanium in the at least one layer comprising titanium, aluminum and nitrogen satisfy Al/Ti>1 by considering only the respective concentrations in atomic percentage of aluminum and titanium in the at least one layer comprising titanium, aluminum and nitrogen, and—the at least one layer comprising titanium, aluminum and nitrogen exhibits wurtzite phase of aluminum nitride and rutile phase of titanium oxide.

A scintillator plate provided with a scintillator having, on a substrate, a first surface facing the substrate and a second surface on an opposite side to the first surface is provided. The scintillator includes needle-like crystals each containing an alkali metal halide compound, thallium iodide, and copper and/or silver as an additive element. The additive element is contained in the second surface at a concentration of not less than 0.04 mol % and not more than 0.5 mol %, and has a higher concentration in the first surface than in the second surface. A thickness of a largest portion of each of the needle-like crystals becomes not less than one time and not more than nine times a thickness at a height of 10 μm in a direction from the first surface to the second surface.

An apparatus for in-vivo measuring H.sub.2O.sub.2 oxidation within a living tissue. The apparatus includes an electrochemical probe and an electrochemical stimulator-analyzer. The electrochemical probe includes a sensing part and a handle. The sensing part includes a working electrode, a counter electrode, and a reference electrode. The working electrode includes a first biocompatible conductive needle coated with a layer of vertically aligned multi-walled carbon nanotubes. The counter electrode includes a second biocompatible conductive needle. The reference electrode includes a third biocompatible conductive needle. The electrochemical stimulator-analyzer is configured to generate a set of electrical currents in a portion of the living tissue.

A method and system is disclosed for creating an optical component having a spatially controlled refractive index and uniform anti-reflective layer. The method may involve alternately depositing and dewetting two or more thin metal material layers on the substrate to form a mask having a spatially varying nano-particle distribution, and with an increased thickness beyond what could be achieved using a single, thick layer of the same material. The substrate may then be etched, using the mask, to imprint a spatially patterned nanostructure pattern on a surface the substrate in accordance with the mask.

A method for fabricating a bi-layer thin film is provided. A first alloy is deposited onto a substrate using a first alloy target to form a first layer of the bi-layer thin film. The first layer may comprise greater than 50 atomic % titanium (Ti) and/or less than 50 atomic % nickel (Ni). The first alloy may be deposited onto the substrate at a first temperature (e.g., room temperature). The substrate may be made of a polymer material, such as poly (4,4′-oxydiphenylene-pyromellitimide) (e.g., Kapton™). A second alloy is deposited onto the first layer using a second alloy target to form a second layer of the bi-layer thin film. The second layer may comprise greater 50 atomic % nickel and/or less than 50 atomic % titanium. The second alloy may be deposited onto the first layer at a second temperature (e.g., room temperature). The bi-layer thin film may exhibit pseudo elasticity and shape memory effect (SME).

A method of filling structures on a substrate uses a semi-dynamic reflow process. The method may include depositing a metallic material on the substrate at a first temperature, heating the substrate to a second temperature higher than the first temperature wherein heating of the substrate causes a static reflow of the deposited metallic material on the substrate, stopping heating of the substrate, and depositing additional metallic material on the substrate causing a dynamic reflow of the deposited additional metallic material on the substrate. RF bias power may be applied during the dynamic reflow to facilitate in maintaining the temperature of the substrate.

Provided is a method for producing a nitride semiconductor photoelectrode capable of improving the light energy conversion efficiency. The method for producing a nitride semiconductor photoelectrode includes a first step of forming an n-type gallium nitride layer on an insulating or conductive substrate, a second step of forming an indium gallium nitride layer on the n-type gallium nitride layer, a third step of forming a nickel layer n the indium gallium nitride layer, and a fourth step of heat-treating the nickel layer in an oxygen atmosphere.

A nanoparticle coater includes a housing; a nanoparticle discharge slot; a first combustion slot; and a second combustion slot.

The present disclosure relates to a method of forming a coating on a blade for a shaver, the method comprising: a first step of evaporating a portion of a supply of a lubricating coating material in a negative pressure chamber, wherein the blade is positioned in the negative pressure chamber adjacent to the supply of the lubricating coating material such that the portion of the lubricating coating material evaporates from the supply and coats the blade; a second step, performed after the first step, of sintering the portion of the lubricating coating material coating the blade by heating the blade to a temperature above the melting temperature of the lubricating coating material; and a third step, performed after the second step, of cooling the blade after sintering to a room temperature.

A forming method of a thin layer with a pore is provided. The method includes forming a thin layer on a substrate, stacking a first mask and a second mask on the thin layer in this order, and forming a pore in the thin layer by dry etching. The first mask includes at least a self-assembling material. The second mask is more resistant to reactive etching or physical etching than the first mask.