Abstract: A uniform thin phase-shifting photomask blank can be formed by depositing a thin film on a substrate by a reactive sputtering technique while passing, at least four times, the substrate over a sputtering target. In the formation of the blank, NO gas is used as the reactive gas, a target composed of a mixture of molybdenum and silicon is used as the sputtering target and a transparent substrate is used as the thin film-forming substrate to form, on the transparent substrate, a light-transmitting film capable of transmitting light rays having an intensity, which cannot substantially contribute to the exposure. In addition, the film is formed, on the substrate, through an opening having a sufficiently enlarged length along the substrate-conveying direction so that even regions whose deposition rate of the target component is not more than 90% of the maximum level thereof also contribute to the film-formation.

Abstract: A method of forming a high quality epitaxial indium phosphide layer on a silicon substrate and a semiconductor device formed by the same method are described. In one aspect, a lead-based perovskite buffer is formed on a silicon substrate, and an epitaxial indium phosphide layer is formed on the lead-based perovskite buffer. In accordance with this approach, relatively large (e.g., up to 300 millimeters in diameter) high quality indium phosphide films may be produced with the relatively high mechanical stability provided by silicon substrates. In this way, intrinsic problems associated with prior approaches that involve growth of high quality indium phosphide thin films on indium phosphide substrates, which are characterized by small wafer size, brittleness and high cost, may be avoided.

Abstract: An embodiment of the instant invention is a method of fabricating a ferroelectric capacitor which is situated over a structure, the method comprising the steps of: forming a bottom electrode on the structure (124 of FIG. 1), the bottom electrode having a top surface and sides; forming a capacitor dielectric (126 of FIG. 1) comprised of a ferroelectric material on the bottom electrode, the capacitor dielectric having a top surface and sides; forming a top electrode (128 and 130 of FIG. 1) on the capacitor dielectric, the top electrode having a top surface and sides, the ferroelectric capacitor is comprised of the bottom electrode, the capacitor dielectric, and the top electrode; forming a barrier layer (118 and 120 of FIG.

Abstract: Unfavorable interactions of ferroelectric dielectric layers with silicon, intermetallic dielectrics, and other materials in metal-oxide semiconductor devices have discouraged the use of ferroelectric memory devices. This invention provides a zirconium titanate barrier layer with high insulating and low leakage characteristics. The barrier layer is not reactive with silicon or other materials used in metal-ferroelectric-semiconductor devices. These thermally stable layers should facilitate the integration of ferroelectric materials into memory and other semiconductor devices.

Abstract: A means to minimize physical distortion and modifications in the electrical properties of ferroelectric films incorporated into semiconductor devices is proposed. By introducing crystallographic texture into these ferroelectric films, the piezoelectric coefficient of the material can be minimized, reducing the interaction between a voltage across and mechanical stress on the film. In addition to having low piezoelectric coefficients, rhombohedral lead zirconate titanate films oriented along (111) exhibit low coercive fields and high remnant polarization, increasing their usefulness in layered semiconductor devices.

Abstract: The present invention provides a bacterium belonging to the genus Bifidobacterium, by which DNA coding for a protein having an antitumor activity or DNA coding for a protein having the activity of converting a precursor of an antitumor substance into the antitumor substance is delivered to tumor tissues specifically under anaerobic conditions thereby expressing the protein encoded by the DNA, as well as a pharmaceutical composition comprising said anaerobic bacterium.

Abstract: A uniform thin phase-shifting photomask blank can be formed by depositing a thin film on a substrate by a reactive sputtering technique while passing, at least four times, the substrate over a sputtering target. In the formation of the blank, NO gas is used as the reactive gas, a target composed of a mixture of molybdenum and silicon is used as the sputtering target and a transparent substrate is used as the thin film-forming substrate to form, on the transparent substrate, a light-transmitting film capable of transmitting light rays having an intensity, which cannot substantially contribute to the exposure. In addition, the film is formed, on the substrate, through an opening having a sufficiently enlarged length along the substrate-conveying direction so that even regions whose deposition rate of the target component is not more than 90% of the maximum level thereof also contribute to the film-formation.

Abstract: A uniform thin phase-shifting photomask blank can be formed by depositing a thin film on a substrate by a reactive sputtering technique while passing, at least four times, the substrate over a sputtering target. In the formation of the blank, NO gas is used as the reactive gas, a target composed of a mixture of molybdenum and silicon is used as the sputtering target and a transparent substrate is used as the thin film-forming substrate to form, on the transparent substrate, a light-transmitting film capable of transmitting light rays having an intensity, which cannot substantially contribute to the exposure. In addition, the film is formed, on the substrate, through an opening having a sufficiently enlarged length along the substrate-conveying direction so that even regions whose deposition rate of the target component is not more than 90% of the maximum level thereof also contribute to the film-formation.