Disclosed is a wiring board including: an insulating substrate; a plurality of connection terminals arranged on the insulating substrate; and a plurality of non-conductive protruding parts respectively arranged on areas of the insulating substrate except areas on which the plurality of connection terminals are arranged. The non-conductive protruding parts has a height greater than that of the connection terminals.

The invention relates to a substrate (1) for electrical circuits comprising at least one first composite layer (2) which is produced by means of roll cladding and, after said roll cladding, has at least one copper layer (3) and an aluminium layer (4) attached thereon, wherein at least the surface side of the aluminium layer (4) facing away from the copper layer (3) is anodized for the generation of an anodic or insulating layer (5) made of aluminium oxide, and wherein the anodic or insulating layer (5) made of aluminium oxide is connected to a metal layer (7) or at least one second composite layer (2) or at least one paper-ceramic layer (11) via at least one adhesive layer (6, 6).

A method of manufacturing a circuit substrate includes the steps of preparing a conductor paste in which a powder of at least one of a metal boride and a metal silicide is added to a powder of silver (Ag), applying the conductor paste to a surface of a ceramic substrate which has been fired, applying a glass paste to the surface of the ceramic substrate after applying the conductor paste, firing the conductor paste applied to the surface so as to form a conductor trace, and firing the glass paste applied to the surface so as to form a coating layer.

One aspect is a logic power module, with at least one logic component, at least one power component and a substrate. The logic element and the power component are provided in separate areas on the substrate. The logic component on the substrate is provided by thick printed copper; and the power component is provided by a metal-containing thick-film layer, and, provided thereon, a metal foil.

A sintered compact includes an alumina phase as a primary phase, and further includes an amorphous phase containing Si and Mn and a cordierite phase. The sintered compact has a porosity of higher than or equal to 1.1% and less than or equal to 5.0%. Preferably, I1/(I1+I2) is greater than or equal to 0.20 and less than or equal to 0.45, where I1 is the strength of the main peak of cordierite obtained by an XRD method, and I2 is the strength of the main peak of alumina.

The present disclosure relates to a multilayer ceramic substrate preparation method. The multilayer ceramic substrate preparation method according to the present disclosure includes firing a plurality of ceramic green sheets, to create a plurality of ceramic thin films; forming a via hall in each of the plurality of ceramic thin films; filling the via hall of the plurality of ceramic thin films with conductive paste, and heat treating the via hall filled with the conductive paste, to form a via electrode; printing a pattern on a cross section of each of the plurality of ceramic thin films, and heat treating the printed pattern, to form an inner electrode; applying a bonding agent on the cross section of each of the ceramic thin films excluding an uppermost ceramic thin film of the plurality of ceramic thin films; aligning and laminating each of the plurality of ceramic thin films such that each of the plurality of ceramic thin films is electrically connected through the via electrode and the inner electrode; and firing or heat treating the laminated plurality of ceramic thin films.

A printed circuit board according to an embodiment of the present invention includes a base film having an insulating property and a conductive pattern disposed on at least one surface of the base film. The conductive pattern includes a copper particle bond layer which is fixed to the base film, and a lightness L* of a conductive pattern non-formed region of the base film is 60 or less. The base film may include a modified layer on one surface side thereof.

A ceramic substrate includes a ceramic layer mainly formed of a glass ceramic and a conductor trace mainly formed of silver (Ag). In an adjacent region located adjacent to the conductor trace, the concentration of boron atoms (B) contained in the ceramic layer increases toward the conductor trace.

A highly conductive transparent glass-based circuit board includes a glass substrate. The glass substrate is a glass-tempered substrate. A surface of the glass-tempered substrate faces air. A conductive paste, printed on the surface of the glass-tempered substrate, is baked, heated, and cooled to form a conductive circuit fused with the surface of the glass-tempered substrate. The surface of the glass-tempered substrate and an upper surface of the conductive circuit are at the same level. A surface of the conductive circuit, except a region reserved for a solder pad used for welding a component, is covered with a printed-circuit-board (PCB) organic solder-resistant layer. The conductive circuit is tightly fused with the glass substrate. It is a fusional relation between the conductive circuit and the glass substrate. A surface of the glass substrate and an upper surface of the conductive circuit are at the same level. Because a surface of the highly conductive transparent glass-based circuit board is smooth, the conductive circuit is not easily damaged. The highly conductive transparent glass-based circuit board has the characteristics of high conductivity and high transmittance.

A method for manufacturing a ceramic substrate that includes forming a mother multilayer body by laminating a ceramic green sheet on a shrinkage suppressing green sheet, the shrinkage suppressing green sheet having a planar shrinkage rate in firing smaller than a planar shrinkage rate in firing of the ceramic green sheet; and forming a recessed portion in the mother multilayer body before firing by pressing a recessed portion formation planned region where the recessed portion is to be formed after firing of the mother multilayer body.