A metal pattern forming method has: producing a first base having a pattern of lyophilic portions which have lyophilic properties with respect to a liquid containing a metal component and liquid-repellent portions which have liquid-repellent properties with respect to the liquid containing a metal component; producing a second base which holds the liquid containing a metal component; and transferring the liquid containing a metal component from the second base to the lyophilic portions of the first base by bringing the first base and the second base into contact with each other. With the metal pattern forming method, it is possible to form a metal pattern with high accuracy in which the metal is prevented from adhering to an unnecessary position on the base.

A pattern forming method comprises dispensing a curable composition onto an underlayer of a substrate; bringing the curable composition into contact with a mold; irradiating the curable composition with light to form a cured film; and separating the cured film from the mold. The proportion of the number of carbon atoms relative to the total number of atoms in the underlayer is 80% or more. The dispensing step comprises a first dispensing step of dispensing a curable composition (A1) substantially free of a fluorosurfactant onto the underlayer, and a second dispensing step of dripping a droplet of a curable composition (A2) having a fluorosurfactant concentration in components excluding a solvent of 1.1% by mass or less onto the curable composition (A1) discretely.

Provided is a conductive laminate including a base material and a conductive ink film provided on the base material, in which a region that extends from a first main surface toward a second main surface to a position being away from the first main surface by a distance equivalent to 50% of a thickness of the conductive ink film has a first void ratio of 15% to 50%, a region that extends from a position being away from the second main surface toward the first main surface by a distance equivalent to 10% of the thickness of the conductive ink film to the second main surface has a second void ratio which is smaller than the first void ratio, and the conductive ink film comprises at least one metal selected from the group consisting of silver, gold, platinum, nickel, palladium, and copper.

A circuit board for a non-combustion flavor inhaler includes a substrate and an electrically conductive ink pattern printed on the substrate. The substrate includes paper. A percentage weight loss of the paper from room temperature to 290° C. is less than 20% of a percentage weight loss of the paper from room temperature to 900° C. under a condition that allows air to flow at a flow rate of 100 mL/min while elevating a temperature of the air at a speed of 10° C./min.

The present invention relates to an assembly to be used in an inkjet printer, an inkjet printer and a method for printing. The assembly comprises (i) a first fixture configured to hold a first print head; and (ii) at least two processing lines A, B, C, D, wherein each processing line A, B, C, D includes a first printing section in which a functional layer is printed on a surface of an electronic device, a sintering section spaced apart from the first printing section and configured to sinter the functional layer, wherein the sintered functional layer exhibits a crystal lattice structure, and a transport mechanism (4) configured to move from the printing section to the sintering section. The first fixture is movable from one processing line A, B, C, D to another processing line A, B, C, D.

A method for manufacturing a wiring board is capable of forming a metal layer included in a wiring layer to have an even thickness. The method includes preparing a conductive first underlayer on a surface of a substrate; a conductive second underlayer on a surface of the first underlayer; and a seed layer on a surface of the second underlayer and containing metal. The method disposes a solid electrolyte membrane between an anode and the seed layer as a cathode; applies voltage between the anode and the first underlayer to form a metal layer on the surface of the seed layer; removes an exposed portion of the second underlayer without the seed layer from the substrate; and removes an exposed portion of the first underlayer without the seed layer from the substrate. The first underlayer is a material having a higher electrical conductivity than that of the second underlayer.

A substrate for a printed circuit board according to an embodiment of the present invention includes a base film having an insulating property, and a conductive layer formed on at least one of surfaces of the base film. In the substrate for a printed circuit board, at least the conductive layer contains titanium in a dispersed manner. The conductive layer preferably contains copper or a copper alloy as a main component. A mass ratio of titanium in the conductive layer is preferably 10 ppm or more and 1,000 ppm or less. The conductive layer is preferably formed by application and heating of a conductive ink containing metal particles. The conductive ink preferably contains titanium or a titanium ion. The metal particles are preferably obtained by a titanium redox process including reducing metal ions using trivalent titanium ions as a reducing agent in an aqueous solution by an action of the reducing agent.

A resin film containing a fluororesin as a main component has, on at least one surface thereof, a pre-treated surface having a content ratio of oxygen atoms or nitrogen atoms of 0.2 atomic percent or more. A coverlay includes the resin film and an adhesive layer laminated on the pre-treated surface. A substrate for a printed wiring board includes the resin film and a conductive layer laminated on the pre-treated surface. A printed wiring board includes an insulating base layer, a conductive pattern laminated on at least one surface of the base layer, and the coverlay for a printed wiring board, the coverlay being laminated on the conductive pattern.

A method of manufacturing a device with a planar electrode structure, the method comprising: (a) forming a microfluidic channel on a substrate; (b) applying a primer layer to at least part of the microfluidic channel, (c) applying a conductive liquid to the microfluidic channel, the conductive liquid comprising electrically conductive particles dispersed in a carrier medium, the carrier medium including a solvent; (d) allowing the conductive liquid to flow throughout the microfluidic channel by capillary action to form the planar electrode structure; and (e) evaporating the solvent from the carrier medium, is described. Devices obtainable using the method and their applications are also described.

Provided is a method for manufacturing a substrate having a concave pattern to be used for forming a high-definition pattern while suppressing wet-spreading and bleeding of a film-forming ink, provided is a composition to be used for manufacturing the substrate, and provided are a method for forming a conductive film, an electronic circuit, and an electronic device. The method for manufacturing a substrate having a concave pattern includes: (i) a step of applying, on a substrate 1, a composition containing a polymer having an acid-dissociable group and an acid generator to form a coating film 2 and (ii) a step of irradiating a predetermined portion of the coating film 2 with radiation. The method for forming a conductive film includes applying a conductive film-forming ink on the concave pattern formed in the exposed portion of the coating film 2 and heating the ink to form a pattern 6. The electronic circuit and the electronic device are provided by using the method for forming a conductive film.