Abstract: Masks for patterning material layers of semiconductor devices, methods of patterning and methods of manufacturing semiconductor devices, and lithography systems are disclosed. A lithography mask includes a pattern of alternating lines and spaces, wherein the lines and spaces comprise different widths. When the lithography mask is used to pattern a material layer of a semiconductor device, the pattern of the material layer comprises alternating lines and spaces having substantially the same width.

Abstract: An embodiment of the invention provides a method for forming a semiconductor device. A method comprises forming a resist on a substrate. A photoacid generator (PAG) is dispersed homogeneously in the resist. The method includes concentrating the PAG near a surface of the resist by evaporating a solvent from the resist. In an embodiment, the concentrating includes heating the resist to a first temperature. Embodiments include forming a topcoat layer on the resist after concentrating the PAG. An embodiment includes exposing the photoresist layer to a level of radiation suitable for generating a photoacid within the photoresist layer.

Abstract: A preferred embodiment of the invention provides a method of spin coating a liquid, such as a resist, onto a surface of a substrate. An embodiment of the invention comprises dispensing a liquid onto the surface; spinning the substrate at a first rotational velocity at least until the liquid forms a substantially uniform film on the surface of the substrate; and spinning the substrate at a second rotational velocity in an opposite direction at least until the liquid reforms a substantially uniform film on the surface of the substrate. Other embodiments include a first rotational acceleration for accelerating the substrate to the first rotational velocity, and a second rotational acceleration for accelerating the substrate to the second rotational velocity. Preferably, the second rotational acceleration is much larger than the first rotational acceleration. Still other embodiments include repeating the first velocity, second velocity sequence one or more times.

Abstract: A preferred embodiment of the invention provides a method of spin coating a liquid, such as a resist, onto a surface of a substrate. An embodiment of the invention comprises dispensing a liquid onto the surface; spinning the substrate at a first rotational velocity at least until the liquid forms a substantially uniform film on the surface of the substrate; and spinning the substrate at a second rotational velocity in an opposite direction at least until the liquid reforms a substantially uniform film on the surface of the substrate. Other embodiments include a first rotational acceleration for accelerating the substrate to the first rotational velocity, and a second rotational acceleration for accelerating the substrate to the second rotational velocity. Preferably, the second rotational acceleration is much larger than the first rotational acceleration. Still other embodiments include repeating the first velocity, second velocity sequence one or more times.

Abstract: A material layer on a substrate being processed, e.g. to form chips, includes one or more functional structures. In order to control pattern density during fabrication of the chip, dummy fill structures of different sizes and shapes are added to the chip at different distances from the functional structures of the material layer. In particular, the placement, size and shape of the dummy structures are determined as a function of a distance to, and density of, the functional structures of the material layer.

Abstract: A material layer on a substrate being processed, e.g. to form chips, includes one or more functional structures. In order to control pattern density during fabrication of the chip, dummy fill structures of different sizes and shapes are added to the chip at different distances from the functional structures of the material layer. In particular, the placement, size and shape of the dummy structures are determined as a function of a distance to, and density of, the functional structures of the material layer.

Abstract: A material layer on a substrate being processed, e.g. to form chips, includes one or more functional structures. In order to control pattern density during fabrication of the chip, dummy fill structures of different sizes and shapes are added to the chip at different distances from the functional structures of the material layer. In particular, the placement, size and shape of the dummy structures are determined as a function of a distance to, and density of, the functional structures of the material layer.

Abstract: A method is described for catalyst-induced growth of carbon nanotubes, nanofibers, and other nanostructures on the tips of nanowires, cantilevers, conductive micro/nanometer structures, wafers and the like. The method can be used for production of carbon nanotube-anchored cantilevers that can significantly improve the performance of scaning probe microscopy (AFM, EFM etc). The invention can also be used in many other processes of micro and/or nanofabrication with carbon nanotubes/fibers. Key elements of this invention include: (1) Proper selection of a metal catalyst and programmable pulsed electrolytic deposition of the desired specific catalyst precisely at the tip of a substrate, (2) Catalyst-induced growth of carbon nanotubes/fibers at the catalyst-deposited tips, (3) Control of carbon nanotube/fiber growth pattern by manipulation of tip shape and growth conditions, and (4) Automation for mass production.

Abstract: A method is described for catalyst-induced growth of carbon nanotubes, nanofibers, and other nanostructures on the tips of nanowires, cantilevers, conductive micro/nanometer structures, wafers and the like. The method can be used for production of carbon nanotube-anchored cantilevers that can significantly improve the performance of scaning probe microscopy (AFM, EFM etc). The invention can also be used in many other processes of micro and/or nanofabrication with carbon nanotubes/fibers. Key elements of this invention include: (1) Proper selection of a metal catalyst and programmable pulsed electrolytic deposition of the desired specific catalyst precisely at the tip of a substrate, (2) Catalyst-induced growth of carbon nanotubes/fibers at the catalyst-deposited tips, (3) Control of carbon nanotube/fiber growth pattern by manipulation of tip shape and growth conditions, and (4) Automation for mass production.