A synthetic paper is manufactured with a method comprising the steps of: a) providing at least two types of pho to-polymerizable monomers, b) exposing the volume to a three-dimensional light pattern to induce a polymerization reaction, and c) removing uncured monomer to create an open microstructure. The volume comprises at least one monomer comprising at least two thiol groups and at least one monomer comprising at least two carbon-carbon double bonds, where the ratio (r.sub.1) between the number of thiol groups and the number of carbon-carbon double bonds fulfils one of: 0.5≦r1≦0.9 and 1.1≦r1≦2. One advantage is that off stoichiometry creates an edge effect giving better defined boundaries between exposed and unexposed parts in the volume and giving a possibility to create thinner micro pillars. Another advantage is that it is easy to bind molecules to the surface to obtain desired surface properties.

In a method for producing a wired circuit board includes a step (1), in which the insulating layer having an inclination face is provided; a step (2), in which a metal thin film is provided on the surface of the insulating layer including the inclination face; a step (3), in which a photoresist is provided on the surface of the metal thin film; a step (4), in which a photomask is disposed so that a first light exposure portion and a second light exposure portion in the photoresist are exposed to light, and the photoresist is exposed to light; a step (5), in which the first light exposure portion and the second light exposure portion are removed; and a step (6), in which the first wire and the second wire are provided on the surface of the metal thin film.

Disclosed herein are methods and apparatuses for exposing an organic metal-oxide film to a blanket UV treatment prior to a lithographic patterning operation. A blanket UV treatment may be used to shift a solubility curve of the film, such that a lower EUV dose may be used to pattern the film. Additionally, a blanket UV treatment may be used after development to further cure the film.

The present disclosure relates to the technical field of semiconductors, and provides a method of processing a photoresist layer, and a photoresist layer. The method of processing a photoresist layer includes: forming a photoresist layer on a target layer, where the photoresist layer includes a first part close to the target layer and a second part away from the target layer; performing first exposure processing on the photoresist layer, and forming an exposure image in the first part of the photoresist layer; processing the second part of the photoresist layer by using a first process, such that the second part forms a third part, where a photosensitivity of the third part is higher than that of the first part; and stripping the third part.

The present disclosure provides a method of forming a photoresist pattern and a projection exposure apparatus. The forming method includes: providing a photoresist layer, and disposing the photoresist layer under a projection objective, wherein a light refracting plate is located between the photoresist layer and the projection objective; and performing an exposure processing on the photoresist layer through the projection objective and the light refracting plate, and forming an exposure image in the photoresist layer, wherein the light refracting plate is configured to reduce a wavelength of optical waves entering the photoresist layer.

The present disclosure relates to the technical field of semiconductors, and provides a method of processing a photoresist layer, and a photoresist layer. The method of processing a photoresist layer includes: forming a photoresist layer on a target layer, where the photoresist layer includes a first part away from the target layer and a second part close to the target layer; processing the photoresist layer by using a first process, such that a light absorption rate of the first part is less than a light absorption rate of the second part; performing first exposure processing on the photoresist layer to form an exposure image in the second part; and stripping the first part and performing first development processing on the photoresist layer, to pattern the second part into a photoresist pattern.

A method of forming a pattern of a semiconductor device includes: forming a first mask pattern comprising first mask lines extending in a first direction in a cell region and second mask lines extending in the first direction in a first core region, the first mask pattern covering a second core region; forming, on the first mask pattern, a second mask pattern comprising third mask lines extending in a second direction in the cell region and fourth mask lines extending in the second direction in the second core region, the second mask pattern covering the first core region; and forming a third mask pattern by using the second mask pattern, the third mask pattern comprising island-type masks in the cell region, fifth mask lines extending in the first direction in the first core region, and sixth mask lines extending in the second direction in the second core region.

A representative method includes forming a photo-sensitive material over a substrate, and forming a cap layer over the photo-sensitive material, and patterning the cap layer. Using the patterned cap layer, a first portion of the photo-sensitive material is selectively exposed to a pre-selected light wavelength to change at least one material property of the first portion of the photo-sensitive material, while preventing a second portion of the photo-sensitive material from being exposed to the pre-selected light wavelength. One, but not both of the following steps is then conducted: removing the first portion of the photo-sensitive material and forming in its place a conductive element at least partially surrounded by the second portion of the photo-sensitive material, or removing the second portion of the photo-sensitive material and forming from the first portion of the photo-sensitive material a conductive element electrically connecting two or more portions of a circuit.

In making an optical component, one or more portions of a substrate's surface are patterned. At least a region of the substrate's surface is coated in negative photoresist, the region encompassing said portions. The negative photoresist becomes undevelopable when exposed to light. Light which forms a grating structure is projected over each of the portions. Light of substantially uniform intensity over the entirety of the region but for the portions, thereby leaving the negative photoresist outside of the portions undevelopable. The negative photoresist is developed so as to embody the grating structure in the photoresist covering the portions. The substrate's surface is patterned to impose the grating structure on the substrate's surface from the developed photoresist; the undevelopable photoresist inhibits patterning of the surface region outside of the portions. The optical component comprises the patterned substrate.

A method of forming a masking element is provided. The method includes forming a photoresist material having a polymer backbone over a substrate, where the polymer backbone includes a linking group that links a first polymer segment to a second polymer segment, each of the first and the second polymer segments having an ultraviolet (UV) curable group. The method includes exposing the photoresist material under a first UV radiation to break the link between the first polymer segment and the second polymer segment. The method includes exposing the photoresist material under a second UV radiation different from the first UV radiation to form a patterned resist layer. And the method includes developing the patterned resist layer to form a masking element.