A photoresist is deposited on a seed layer on a substrate. A first region of the photoresist is removed to expose a first portion of the seed layer to form a via-pad structure. A first conductive layer is deposited onto the first portion of the seed layer. A second region of the photoresist adjacent to the first region is removed to expose a second portion of the seed layer to form a line. A second conductive layer is deposited onto the first conductive layer and the second portion of the seed layer.

A method of manufacturing an electrode substrate for a transparent light emitting device display that includes laminating copper foil on a transparent base material; forming a copper foil pattern by etching the copper foil; forming a transparent photosensitive resin composition layer on a front surface of the transparent base material and the copper foil pattern; and exposing at least a part of the copper foil pattern by removing at least a part of the transparent photosensitive resin composition layer provided on the copper foil pattern.

A method includes: providing a first layout of a first layer over a substrate, the first layer having at least one metal pattern, and generating a second layout by placing a cut mask at a first position relative to the substrate to remove material from a first region of the at least one metal pattern to provide a first metal pattern and placing the cut mask at a second position relative to the first layer over the substrate to remove material from a second region of the at least one metal pattern to provide a second metal pattern.

A method includes patterning a layer over a substrate with a first metal pattern; using a cut mask in a first position relative to the substrate to perform a first cut patterning for removing material from a first region within the first pattern; and using the same cut mask to perform a second cut patterning while in a second position relative to the same layer over the substrate, for removing material from a second region in a second metal pattern of the same layer over the substrate.

A method for producing a glass substrate according to the present invention includes the steps of: (I) forming a through hole (11) in a glass sheet (10); (II) forming a resin layer (20) on a first principal surface of the glass sheet (10) using a resin composition sensitive to light having a predetermined wavelength .sub.1; (III) photoexposing an area of the resin layer (20) that covers the through hole (11) by irradiating the area with light U having the wavelength .sub.1 and applied from the direction of a second principal surface of the glass sheet (10); and (IV) forming a through-resin hole (21) by removing the area photoexposed in the step (III). The glass sheet (10) protects the resin layer (20) from the light U so as to prevent the resin layer (20) from being photoexposed by beams of the light U that are incident on the second principal surface of the glass sheet (10) in the step (III).

The exposure head is for irradiating a substrate conveyed in a predetermined direction with an exposure beam while scanning the substrate with the exposure beam in a one-dimensional manner, and the exposure head includes: a polygon mirror having multiple reflecting surfaces and provided rotatably; an optical element configured to cause the beam emitted from a light source and shaped into a beam shape to enter the polygon mirror; an imaging optical system configured to image the beam reflected by the polygon mirror onto an exposure surface of the substrate, a reflecting mirror provided insertably into or removably from the optical path of the beam shaped into the beam shape entering the optical element, the reflecting mirror being configured to reflect the beam in a direction different from the optical path while being inserted into the optical path; and a light-receiving element arranged at a position where the beam reflected by the reflecting mirror can enter the light-receiving element, and that is capable detecting an intensity of the beam.

A method for producing a glass substrate according to the present invention includes the steps of: (I) forming a through hole (11) in a glass sheet (10); (II) forming a resin layer (20) on a first principal surface of the glass sheet (10) using a resin composition sensitive to light having a predetermined wavelength .sub.1; (III) photoexposing an area of the resin layer (20) that covers the through hole (11) by irradiating the area with light U having the wavelength .sub.1 and applied from the direction of a second principal surface of the glass sheet (10); and (IV) forming a through-resin hole (21) by removing the area photoexposed in the step (III). The glass sheet (10) protects the resin layer (20) from the light U so as to prevent the resin layer (20) from being photoexposed by beams of the light U that are incident on the second principal surface of the glass sheet (10) in the step (III).

A method for curing solder paste on a thermally fragile substrate is disclosed. An optically reflective layer and an optically absorptive layer are printed on a thermally fragile substrate. Multiple conductive traces are selectively deposited on the optically reflective layer and on the optically absorptive layer. Solder paste is then applied on selective locations that are corresponding to locations of the optically absorptive layer. After a component has been placed on the solder paste, the substrate is irradiated from one side with uniform pulsed light. The optically absorptive layer absorbs the pulsed light and becomes heated, and the heat is subsequently transferred to the solder paste and the cornponent via thermal conduction in order to heat and melt the solder paste.

The present disclosure concerns an electrical circuit pattern on a substrate, as well as a method and system for forming same. In a typical embodiment, a light pattern is projected through a transparent layer to cause a patterned release of adhesion between a continuous material layer and the transparent layer. A release layer adhered to the patterned material layer is pulled off the substrate to separate the material having lower adhesion while leaving the material that was not exposed to form the electrical circuit pattern thereon.

A printed circuit board is disclosed. The printed circuit board includes: a substrate layer; a copper layer disposed on the substrate layer; and an organic solderability preservative (OSP) layer disposed on the copper layer. The OSP layer defines one or more laser treated OSP surfaces.