The present invention relates to a method for manufacturing metal timepiece components, characterised in that it comprises the steps of forming a multi-level photoresist mould, by means of a UV-LIGA type method, and of galvanically depositing a layer of at least one metal starting from at least two conductive layers so as to form a block that substantially reaches the top surface of the photoresist.

A method and apparatus for forming a resist pattern may be provided. In the method for forming a resist pattern, a resist layer may be formed on a base layer, an electric field may be applied to the resist layer in a thickness direction of the resist layer, and a portion of the resist layer may be exposed with extreme ultraviolet (EUV) light while applying the electric field. A lithography apparatus for performing the method of forming a resist pattern may include at least an exposure part and an electric field forming part. The exposure part may be configured to expose a portion of the resist layer with extreme ultraviolet (EUV) light. The electric field forming part may be configured to apply an electric field to the resist layer.

Photoresist layers of semiconductor components including electric fields. The photoresist layer may include a body including a first portion disposed directly over a conductive layer of the semiconductor component. The body may also include a second portion integrally formed with and positioned over the first portion. The second portion may include a surface formed opposite the first portion. Additionally, the second portion may include a plurality of charged-particles implanted therein, where the plurality of charged-particles generating an electric field may extend through the first portion and the second portion of the body.

A method and apparatus for applying an electric field and/or a magnetic field to a photoresist layer without air gap intervention during photolithography processes is provided herein. The method and apparatus include an electrode assembly and a base assembly. The electrode assembly includes a permeable electrode. The base assembly includes one or more process fluid channels disposed around a circumference of the substrate support surface and configured to fill a process volume with a process fluid. The electrode assembly is configured to apply an electric field to a substrate disposed within the process volume.

A method of manufacturing a printed circuit board a includes preparing an insulating substrate on which a first metal layer is formed, stacking a resist laminate having a plurality of layers on the first metal layer, forming an opening exposing a portion of the first metal layer by patterning the stacked resist laminate having the plurality of layers, forming a second metal layer on the exposed portion of the first metal layer, removing the patterned resist laminate having the plurality of layers, and etching at least another portion of the first metal layer.

A display substrate includes a base substrate; and a single pixel definition layer on the base substrate defining a plurality of subpixel apertures. The single pixel definition layer includes a plurality of hydrophobic particles dispersed in a main body for enhancing hydrophobicity of a portion of the single pixel definition layer.

A method for photoresist-free photolithography to pattern a surface of conductor or semiconductor substrate and deposit a material includes surface cleaning and irradiating a surface through a mask with VUV photons from a lamp. Photons are generated with a VUV lamp having a wavelength of 160 nm-200 nm and with an intensity sufficient to alter the surface. The photons are directed through a mask pattern to alter the surface chemistry or structure in those areas of the substrate defined by the mask. Material is selectively deposited onto the surface, in those portions of the surface that are exposed to the VUV photons, or unexposed to the VUV photons, depending on the substrate surface. A method uses a seed film and then electroplates metal onto the seed film in the mask pattern. A method provides for electroless deposition of metal and another for altering surface chemistry in the mask pattern.

A method and apparatus for forming a resist pattern may be provided. In the method for forming a resist pattern, a resist layer may be formed on a base layer, an electric field may be applied to the resist layer in a thickness direction of the resist layer, and a portion of the resist layer may be exposed with extreme ultraviolet (EUV) light while applying the electric field. A lithography apparatus for performing the method of forming a resist pattern may include at least an exposure part and an electric field forming part. The exposure part may be configured to expose a portion of the resist layer with extreme ultraviolet (EUV) light. The electric field forming part may be configured to apply an electric field to the resist layer.

A method and apparatus for applying an electric field and/or a magnetic field to a photoresist layer without air gap intervention during photolithography processes is provided herein. The method and apparatus include an electrode assembly and a base assembly. The electrode assembly includes a permeable electrode. The base assembly includes one or more process fluid channels disposed around a circumference of the substrate support surface and configured to fill a process volume with a process fluid. The electrode assembly is configured to apply an electric field to a substrate disposed within the process volume.

A display substrate includes a base substrate; and a single pixel definition layer on the base substrate defining a plurality of subpixel apertures. The single pixel definition layer includes a plurality of hydrophobic particles dispersed in a main body for enhancing hydrophobicity of a portion of the single pixel definition layer.