A photosensitive insulating paste according to preferred embodiments of the present disclosure contains glass frit, a first inorganic filler, a second inorganic filler, an alkali-soluble polymer, a photosensitive monomer, a photopolymerization initiator, and a solvent. The first inorganic filler has a refractive index of 1.7 or higher. The second inorganic filler has a refractive index of 1.55 or lower. An electronic component according to preferred embodiments of the present disclosure is produced by using the photosensitive insulating paste.

A ceramic carrier substrate for an electrical/electronic circuit. The substrate includes ceramic layers arranged one above the other in an interconnected structure and conductor tracks arranged on and/or in individual ceramic layers and connected to one another as the conductor structure for the electrical/electronic circuit. The interconnected structure is formed by a firing operation. A first conductor substructure is formed in a first interconnected structure subassembly which comprises at least one of the ceramic layers, and a second conductor substructure is formed in a second interconnected structure subassembly which is directly adjacent to the first interconnected structure subassembly and comprises at least one of the ceramic layers. The second conductor substructure substantially consists of high-current conductor tracks and is configured to contact a power circuit. The first conductor substructure substantially consists of signal conductor tracks and is configured to contact a drive circuit for the power circuit.

[Problem] To realize high reliability and high functionalization while suppressing characteristics variation in a multilayer interconnection substrate used in a microwave or millimeter-wave band integrated with an antenna. [Resolution Means] A multilayer substrate for high frequency with an antenna element formed on a surface. The multilayer substrate for high frequency has an intermediate substrate. The intermediate substrate consists of a low-temperature co-fired glass-ceramic substrate and has intermediate insulating layers consisting of a glass-ceramic and an internal conductor formed between these intermediate insulating layers. A surface insulating layer consisting of an organic material having a dielectric constant lower than a glass-ceramic material is stacked on a surface of the intermediate substrate. An outer-side via conductor penetrating this surface insulating layer is configured by a sintered metal that forms a metallic bond with a wiring conductor in the substrate. The outer-side via conductor is formed at the same time as sintering the glass-ceramic multilayer substrate.

Disclosed is a wiring board having a plurality of insulating layers and at least one wiring layer each formed between adjacent two of the plurality of insulating layers such that, when a cross section of the wiring layer is taken in parallel to a thickness direction, at least one corner portion of the cross section of the wiring layer is rounded.

A conductive paste having a viscosity suitable for filling a hole of a board, long pot life, and excellent conductivity and long-term reliability of a cured product, and a multilayer board using the same are provided. A conductive paste comprising with respect to (A) 100 parts by mass of dimer acid-modified epoxy resin, (B) from 200 to 1900 parts by mass of high melting metal powder containing silver-coated copper alloy powder and having a melting point of 800 C. or higher, (C) from 400 to 2200 parts by mass of silver-coated copper alloy powder having a melting point of 800 C. or higher, (D) from 1.0 to 20.0 parts by mass of curing agent containing a hydroxy group-containing aromatic compound, and (E) from 5.0 to 100.0 parts by mass of a flux containing polycarboxylic acid, is used as the present invention.

A multilayer wiring substrate that can realize a higher-density wiring structure is obtained. Provided is a multilayer wiring substrate, where a multilayer body including a first insulating layer and a second insulating layer stacked on the bottom surface of the first insulating layer includes printed wiring electrodes; the printed wiring electrodes are formed by printing with and sintering conductive paste; the printed wiring electrodes respectively include first wiring electrode portions located on the second insulating layer and second wiring electrode portions respectively joined to first wiring electrode portions; and the second wiring electrode portions respectively extend into through holes and, further, are exposed at the top surface of the first insulating layer.

The present invention relates to layer manufacturing, more particularly to a method for additive layer manufacturing of objects comprised of more than one material with free-form capability for all included materials. The invention can for example be used for producing packaging for Microsystems where the ceramic acts as an insulator and the secondary material is used to produce electrical or optical 3D conductor lines or electrical or optical 3D vias. The fine powder used in this method enables it to be used for building components with small feature size and demand for high precision. Other intended uses for this method is to build small mechanical precision parts or grinding tools, dental objects or medical implants.