A laminate that includes a metal layer that is not easily separated from a substrate, a method for producing the laminate, and a method for forming a fine conductive pattern that exhibits high conductivity, are disclosed. The peel strength of a metal layer included in a laminate that includes a polymer layer provided between a substrate and the metal layer is improved by implementing a structure in which the metal that forms the metal layer is chemically bonded to COO that extends from the polymer main chain that forms the polymer layer at the interface between the metal layer and the polymer layer. A fine conductive pattern that exhibits high conductivity can be formed by applying UV light to a pattern area of an insulating film formed on a substrate, and applying an ink prepared by dispersing metal nanoparticles in a solvent to the substrate to effect adhesion and aggregation of the ink in the pattern area, the surface of the metal nanoparticles being protected by an organic molecule layer.

A circuit board is provided, including: a core board, defining a plurality of slots, the plurality of slots including a plurality of first sub-slots and a plurality of second sub-slots disposed beneath the first sub-slots. Each of the second sub-slots is located beneath a corresponding first sub-slot of the first sub-slots; and a plurality of chip assemblies, arranged in the slots and including a plurality of first chips located in the first sub-slots and a plurality of second chips located in the second sub-slots. Each of the first chips is connected in series with one of the second chips at a corresponding position to form a plurality of chipsets; the chipsets are connected in parallel with each other; an end of the chipsets is connected to a first power signal layer, and the other end of the plurality of chipsets is connected to a ground layer.

A bidirectional self-healing neural interface includes a first elastic substrate; a neural electrode disposed on the first elastic substrate and comprising a conductive polymer composite; and a second elastic substrate disposed on the neural electrode. The conductive polymer composite includes a matrix formed of a self-healing polymer material; and a plurality of electrical conductor clusters distributed in the matrix. Each of the electrical conductor clusters includes particles of a first electrical conductor; and a plurality of particles of a second electrical conductor formed of the same material as that of the first electrical conductor, distributed around each of the particles of the first electrical conductor, and having sizes that are smaller than those of the particles of the first electrical conductor. The first electrical conductor is a source for generating the second electrical conductor. The neural interface has excellent elasticity, electrical conductivity that is improved by deformation, and is self-healing.

A conductive glass substrate, and a system and a method for manufacturing the same are provided. The conductive glass substrate includes a glass substrate structure, a conductive base structure and a conductive extending structure. The glass substrate structure includes at least one through hole connected between a bottom surface and a top surface thereof. The conductive base structure is disposed on the bottom surface of the glass substrate structure. The conductive extending structure is electrically connected to the conductive base structure, and the conductive extending structure is extended from the conductive base structure to the top surface of the glass substrate structure along an inner surface of the at least one through hole. Hence, the conductive glass substrate can provide at least one conductive via so as to electrically connect an upper circuit and a lower circuit.

An electroconductive substrate including a base material and a metal wiring made of at least either of silver and copper, and the electroconductive substrate has an antireflection region formed on part or all of the metal wiring surface. This antireflection region is composed of roughened particles made of at least either of silver and copper and blackened particles finer than the roughened particles and embedded between the roughened particles. The blackened particles are made of silver or a silver compound, copper or a copper compound, or carbon or an organic substance having a carbon content of 25 wt % or more. The antireflection region has a surface with a center line average roughness of 15 nm or more and 70 nm or less. The electroconductive substrate is formed from metal wiring from a metal ink that forms roughened particles, followed by application of a blackening ink containing blackened particles.

The invention, which relates to the technical field of circuit boards, specifically discloses a method for manufacturing an embedded circuit board, an embedded circuit board, and an application thereof. The method includes: providing a substrate, wherein an electronic component is embedded in the substrate, a pad is arranged on a side surface of the electronic component, and an end surface of the pad is flush with a same side surface of the substrate; forming a metallic layer on a side surface of the substrate adjacent to the pad by sputtering, evaporation, electroplating or chemical vapor deposition; and patterning the metallic layer to obtain a circuit board covered with the metallic layer on the pad, wherein the metallic layer on the pad protrudes beyond the same side surface of the substrate.

According to various embodiments, an article including a glass or glass-ceramic substrate having a first major surface and a second major surface, and a via extending through the substrate from the first major surface to the second major surface over an axial length, L, the via defining a first axial portion, a third axial portion, and a second axial portion disposed between the first and third axial portions. The article further includes a helium hermetic adhesion layer disposed on the interior surface in the first and/or third axial portions and a metal connector disposed within the via, the metal connector being adhered to the helium hermetic adhesion layer. The metal connector fully fills the via over the axial length, L, the via has a maximum diameter, Φ.sub.max, of less than or equal to 30 μm, and the axial length, L, and the maximum diameter, Φ.sub.max, satisfy an equation: $\frac{L}{\sqrt{{\Phi }_{\max }}}>20{\mathrm{micron}}^{1/2}.$

An inductor assembly and a manufacturing method for an inductor assembly are provided. The inductor assembly includes a circuit board, a magnetic component, and a winding wire. The circuit board defines a groove body, the magnetic component is embedded in the groove body, and the winding wire is arranged on the magnetic component, surrounds along a thickness direction of the magnetic component, and is electrically connected to the circuit board

A wiring circuit board includes a metal support board, a first metal thin film, an insulating layer, a second metal thin film, and a conductive layer in a thickness direction order. The insulating layer includes a through hole penetrating in the thickness direction, which includes a first opening end at the first metal thin film side, a second opening end opposite to the first opening end, and an inner wall surface between the first and-the second opening ends. The first metal thin film includes a first opening portion, which overlaps the first opening end in a projection view in the thickness direction. The second metal thin film includes a second opening portion, which overlaps the first opening portion and the second opening end in a projection view in the thickness direction. The conductive layer has a via portion disposed in the through hole and connected to the metal support board.

The present application provides a circuit board and a manufacturing method therefor. The circuit board includes: a core board, at least one chip, a first circuit layer, and a first insulating layer. A groove body is formed on the core board. The chip is provided in the groove body. The chip is provided with a first lead-out terminal. The first circuit layer is provided on at least one side of the core board. The first insulating layer is provided between the core board and the first circuit layer. The first lead-out terminal passes through the first insulating layer and is connected to the first circuit layer, so that the chip is electrically connected to the first circuit layer. Thus, the wiring between the chip and the circuit is more flexible.