An automated masking system includes a substrate loading apparatus designed to hold a plurality of substrates, a first masking material application station designed to automatically apply a first masking material to a portion of the substrate, and a second masking material application station designed to automatically apply a second masking material to a portion of the substrate, the second masking material being different than the first masking material. The system includes a first dispensing apparatus and a second dispensing apparatus that move relative to the substrate in a repeatable motion. The substrate moves automatically from the first masking material application station to the second masking material application station.

In a method for manufacturing a multilayer substrate for having a BGA-type component thereon, a conductive through hole for restricting a signal interference and a resist film are formed on the multilayer substrate, an occurrence of a fault caused by a residual of a resist in the conductive through hole is reduced. In the method for manufacturing the multilayer substrate for having the BGA-type component thereon, a step of forming the resist film includes an applying step of applying a photosensitive resist to an entirety of a front surface portion of a base. The applying step is performed while restricting the resist from entering the conductive through hole by supplying a high pressure air to a rear surface of the base to pass through the conductive through hole using an air supply mechanism.

A pattern is formed by arranging a photocurable composition on a substrate; bringing a mold having a concavo-convex pattern into contact with the composition; irradiating the composition with light to form a cured film; releasing the mold from the cured film; forming a reversal layer on the cured film having a concavo-convex pattern transferred from the mold; partially removing the reversal layer to expose the convexes of the pattern in such a manner that the reversal layer remains in the concaves of the pattern formed on the cured film; and etching the photocurable composition layer using the reversal layer remaining in the concaves as a mask to form a reversal pattern, wherein the mold is brought into contact with the photocurable composition in an atmosphere of a soluble gas having a solubility in the composition; and the soluble gas has a saturation solubility of 38% by volume or more.

A nanoimprint liquid material in which the particle number concentration of particles having a particle diameter of 0.07 m or more is less than 310/mL is provided.

A printing process for printing an ink pattern on a substrate is provided. The ink pattern to be printed is based on an available pattern layout. The pattern layout defines a desired layout of the ink pattern to be printed. Based on the pattern layout an input image for allocating dot positions of the ink pattern is generated. The printing process includes a step of comparing a scan image with the input image to carry out a quality inspection to detect any print defects in the printed ink pattern. The printing process includes a step of providing a decision on an approval or a rejection of the printed ink pattern. In case of an approval, the substrate can be supplied to a subsequent processing station to finalise the substrate. In case of a rejection, the substrate including print defects can be recycled.

A multilayer wiring board has a high degree of freedom of wiring design and can realize high-density wiring, and a method to simply manufacture the multilayer wiring board. A core substrate with two or more wiring layers provided thereon through an electrical insulating layer. The core substrate has a plurality of throughholes filled with an electroconductive material, and the front side and back side of the core substrate have been electrically conducted to each other by the electroconductive material. The throughholes have an opening diameter in the range of 10 to 100 m. An insulation layer and an electroconductive material diffusion barrier layer are also provided, and the electroconductive material is filled into the throughholes through the insulation layer. A first wiring layer provided through an electrical insulating layer on the core substrate is connected to the electroconductive material filled into the throughhole through via.

A method for printing on a substrate, the method may include determining actual locations of substrate holes; printing a first ink on an object at locations that correspond to the actual locations of the substrate holes and curing the first ink to provide a holes mask; and wherein after the substrate is positioned on the object so that holes mask seals bottoms of the substrate holes then printing the second ink on the substrate thereby forming a predefined pattern on the substrate.

In an example, a process for reversibly bonding a conformal coating to a dry film solder mask (DFSM) material is disclosed. The process includes applying a first conformal coating material to a DFSM material. The first conformal coating material includes a first functional group, and the DFSM material includes a second functional group that is different from the first functional group. The process also includes reversibly bonding the first conformal coating material to the DFSM material via a chemical reaction of the first functional group and the second functional group.

In an example, a process for reversibly bonding a conformal coating to a dry film solder mask (DFSM) material is disclosed. The process includes applying a first conformal coating material to a DFSM material. The first conformal coating material includes a first functional group, and the DFSM material includes a second functional group that is different from the first functional group. The process also includes reversibly bonding the first conformal coating material to the DFSM material via a chemical reaction of the first functional group and the second functional group.

A multilayer wiring board has a high degree of freedom of wiring design and can realize high-density wiring, and a method to simply manufacture the multilayer wiring board. A core substrate with two or more wiring layers provided thereon through an electrical insulating layer. The core substrate has a plurality of throughholes filled with an electroconductive material, and the front side and back side of the core substrate have been electrically conducted to each other by the electroconductive material. The throughholes have an opening diameter in the range of 10 to 100 m. An insulation layer and an electroconductive material diffusion barrier layer are also provided, and the electroconductive material is filled into the throughholes through the insulation layer. A first wiring layer provided through an electrical insulating layer on the core substrate is connected to the electroconductive material filled into the throughhole through via.