A method for making a circuit board comprising: providing a silver clad laminate comprising a substrate and two silver foils; forming at least one through hole on the silver clad laminate, the through hole comprises an annular middle wall and two annular edge walls connected to two sides of the annular middle wall; forming an organic conductive film on the annular middle wall; forming a dry film pattern layer on the second area; plating copper to form a copper circuit layer on the first area, and to form a via hole in the through hole; removing the dry film pattern layer; and etching the second area of the silver foil away. The first area changes to a silver circuit layer. The copper circuit layer and the silver circuit layer define a conductive circuit layer. A circuit board made by the method is also provided.

An ink contains particles containing metal that reacts during sintering to produce an electrically conductive line or area having a diffusivity that is less than the diffusivity of the metal before the reaction. Resulting electronic circuits therefore exhibit longer useful lives, compared to conventionally inkjet printed circuits.

A method of making a device patterned with one or more electrically conductive features includes depositing a conductive material layer over an electrically insulating surface of a substrate, depositing an anti-corrosive material layer over the conductive material layer, and depositing an etch-resist material layer over the anti-corrosive material layer. The etch-resist material layer may be deposited over the anti-corrosive material layer, and the anti-corrosive material layer forming a bi-component etch mask in a pattern resulting in covered portions of the conductive material layer and exposed portions of the conductive material layer, the covered portions being positioned at locations corresponding to one or more conductive features of the device. A wet-etch process is performed to remove the exposed portions of the conductive material layer from the electrically insulating substrate, and the bi-component etch mask is removed to expose the remaining conductive material. Systems and devices relate to devices with patterned features.

An ink contains particles containing metal that reacts during sintering to produce an electrically conductive line or area having a diffusivity that is less than the diffusivity of the metal before the reaction. Resulting electronic circuits therefore exhibit longer useful lives, compared to conventionally inkjet printed circuits.

The present disclosure relates to SMD mounting. The teachings thereof may be embodied in heating elements having a mounting side for SMD mounting, the mounting side being available for placing onto a substrate, for example in the form of a circuit carrier, electronic assemblies with a circuit carrier and a component, and/or methods for producing an electronic assembly having a circuit carrier and a component placed on the circuit carrier. For example, a heating element may include: a mounting side for SMD mounting; a housing enclosing a cavity; and a reactive substance in the cavity that reacts exothermically at a reaction temperature T.sub.1.

The present disclosure relates to SMD mounting. The teachings thereof may be embodied in heating elements having a mounting side for SMD mounting, the mounting side being available for placing onto a substrate, for example in the form of a circuit carrier, electronic assemblies with a circuit carrier and a component, and/or methods for producing an electronic assembly having a circuit carrier and a component placed on the circuit carrier. For example, a heating element may include: a mounting side for SMD mounting; a housing enclosing a cavity; and a reactive substance in the cavity that reacts exothermically at a reaction temperature T.sub.1.

Self-sintering conductive inks can be printed and self-sintered with a simple and low-cost process mechanized by exothermic alkali metal and water reaction, with enhanced electrical and thermal performance by liquid metal fusion. Such self-sintering conductive inks may include a gallium-alkali metal component and a water absorbing gel component. After patterning, the self-sintering inks, on reaching a designed trigger temperature (including room temperature), may metallize through a two-step process. Initially the gallium-alkali metal component activates and reacts with water released from the water absorbing gel component. Then the exothermic reaction between the water and the alkali element creates an intense and highly localized heating effect, which liquefies all metallic components in the ink and, on cooling, creates a solid metal trace or interconnect. Post cooling, the metal trace or interconnect cannot be reflowed without a significant temperature increase or other energetic input.

Highly reliable interconnections for microelectronic packaging. In one embodiment, dielectric layers in a build-up interconnect have a gradation in glass transition temperature; and the later applied dielectric layers are laminated at temperatures lower than the glass transition temperatures of the earlier applied dielectric layers. In one embodiment, the glass transition temperatures of earlier applied dielectric films in a build-up interconnect are increased through a thermosetting process to exceed the temperature for laminating the later applied dielectric films. In one embodiment, a polyimide material is formed with embedded catalysts to promote cross-linking after a film of the polyimide material is laminated (e.g., through photo-chemical or thermal degradation of the encapsulant of the catalysts). In one embodiment, the solder resist opening walls have a wettable layer generated through laser assisted seeding so that there is no gap between the solder resist opening walls and no underfill in the solder resist opening.

The present invention is directed to energy curable offset conductive inks and hybrid offset conductive ink compositions that contain an oxidative curable ink and the energy curable offset conductive ink. The conductive inks and ink compositions exhibit low levels of resistance and hence have superior conductivity.

An electronic device may have housing structures, electrical components, and other electronic device structures. Adhesive may be used to join electronic device structures. Adhesive may be dispensed as liquid adhesive and cured to form adhesive joints. Adhesive joints may be debonded. Chain reactions may be initiated by applying a localized initiator such as a chemical or localized energy to the adhesive. Once initiated, the chain reaction may spread throughout the adhesive to cure the adhesive, to globally change adhesive viscosity, or to weaken the adhesive to facilitate debonding. Local changes to adhesive may also be made such as local increases and decreases to adhesive viscosity. Chain reaction curing may be used to cure adhesive or debond adhesive that is hidden from view within gaps in the electronic device structures. Viscosity changes may be used to control where adhesive flows.