A flexible laminated sheet manufacturing method includes thermocompression-bonding an insulation film formed of a liquid crystal polymer onto a metal foil between endless belts to form a flexible laminated sheet. The thermocompression bonding includes heating the flexible laminated sheet so that the maximum temperature of the sheet is in the range from a temperature that is 45° C. lower than the melting point of the liquid crystal polymer to a temperature that is 5° C. lower than the melting point. The thermocompression bonding also includes slowly cooling the flexible laminated sheet so that an exit temperature, which is a temperature of the sheet when transferred out of the endless belts, is in the range from a temperature that is 235° C. lower than the melting point of the liquid crystal polymer to a temperature that is 100° C. lower than the melting point.

An extremely thin copper foil is provided that enables formation of highly fine different wiring patterns with a line/space (L/S) of 10 μm or less/10 μm or less on two sides of the copper foil and is thus usable as an inexpensive and readily processable substitution for silicon and glass interposers. The extremely thin copper foil includes, in sequence, a first extremely thin copper layer, an etching stopper layer, and the second extremely thin copper layer. Two sides of the extremely thin copper foil each have an arithmetic average roughness Ra of 20 nm or less.

An insulated circuit board having a ceramic substrate, a circuit layer on which a circuit pattern is formed and that is bonded to one surface of the ceramic substrate, and a metal layer bonded to the other surface of the ceramic substrate. The circuit layer has a first circuit layer that is bonded to the ceramic substrate and is made of aluminum and a second circuit layer that is bonded to the upper surface of the first circuit layer and is made of copper, the metal layer has a first metal layer that is bonded to the ceramic substrate and is made of aluminum and a second metal layer that is bonded to the upper surface of the first metal layer and is made of copper, and the thicknesses of the first circuit layer and the first metal layer are each 0.2 mm or more and 0.9 mm or less.

A wiring board, a multilayer wiring board, and a method of manufacturing a wiring board adapted to make the filling of through holes and the formation of fine wiring patterns. The wiring board comprises an insulator; a through hole between front and back surfaces of the insulator; a through hole conductor for electrically connecting front and back surface side openings; through hole lands around the front and the back surface side openings, and connected to the through hole conductor; lid plating conductors on the front and the back surface sides, and placed on the respective through hole lands; and wiring patterns formed on the front are compatible and the back surface of the insulator. The thickness of the through hole lands is 1.0 m or more and 10.0 m or less, and the area of each lid plating conductor is less than the area of each through hole land.

A patterning paste is disclosed for patterning metal nanowires, the patterning paste including a complexing agent containing guanidine thiocyanate. A method of selectively patterning a substrate having metal nanowires includes: providing a substrate having a surface bearing metal nanowires; and selectively applying the patterning paste to the substrate such that the metal nanowires are selectively cut into a pattern. A consumer electronic product includes: a substrate having a surface bearing metal nanowires. The metal nanowires of the substrate are selectively patterned by applying the patterning paste to the substrate such that the metal nanowires are selectively cut into the pattern.

A manufacturing method of a circuit substrate comprises the steps of providing a laminated substrate comprising an insulating layer and a circuit layer disposed on the insulating layer; forming a photoresist layer on the circuit layer; mechanically cutting the photoresist layer and a part of the circuit layer to form gaps; etching the circuit layer in the gaps until a surface of the insulating layer is exposed to form a circuit layout; and removing the photoresist layer to form the circuit substrate.

An insulated circuit board having a ceramic substrate, a circuit layer on which a circuit pattern is formed and that is bonded to one surface of the ceramic substrate, and a metal layer bonded to the other surface of the ceramic substrate. The circuit layer has a first circuit layer that is bonded to the ceramic substrate and is made of aluminum and a second circuit layer that is bonded to the upper surface of the first circuit layer and is made of copper, the metal layer has a first metal layer that is bonded to the ceramic substrate and is made of aluminum and a second metal layer that is bonded to the upper surface of the first metal layer and is made of copper, and the thicknesses of the first circuit layer and the first metal layer are each 0.2 mm or more and 0.9 mm or less.

Disclosed is a stretchable member with a metal foil including a stretchable resin base material, and a conductive metal foil provided on the stretchable resin base material. A surface of the metal foil on the stretchable resin base material side is a roughened surface having surface roughness Ra of 0.1 m to 3 m.

A method of fabricating a multilayer superconducting printed circuit board comprises first, forming a bimetal foil to overlie a substrate, the bimetal foil comprising a first layer of a first metal, a layer of a second metal, and a second layer of the first metal, and then etching the second layer of the first metal. Forming a bimetal foil to overlie a substrate may include forming a bimetal foil comprising a first layer of a normal metal, a layer of a superconducting metal, and a second layer of the normal metal. Etching the second layer of the first metal may include preparing a patterned image in the second layer of the first metal for etching, processing the patterned image through a cleaner, rinsing the patterned image, and then, immersing the patterned image in a microetch.

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.