A bonding member that includes a base material that has a spiral shape when viewing a cross section thereof orthogonal to a longitudinal direction thereof, and contains a low melting point metal; and a coating film in a gap between opposed surfaces of the base material when the base material is in the spiral shape. The coating film contains metal particles of a high melting point metal that forms an intermetallic compound having a melting point higher than that of the low melting point metal by reaction of the high melting point metal with a melt of the low melting point metal. The low melting point metal is, for example, Sn or a Sn alloy. The high melting point metal is, for example, a CuNi alloy, a CuMn alloy, a CuCr alloy, or a CuAl alloy.

Methods are provided for controlling voiding caused by gasses in solder joints of electronic assemblies. In various embodiments, a preform can be embedded into the solder paste prior to the component placement. The solder preform can be configured with a geometry such that it creates a standoff, or gap, between the components to be mounted in the solder paste. The method includes receiving a printed circuit board comprising a plurality of contact pads; depositing a volume of solder paste onto each of the plurality of contact pads; depositing a solder preform into each volume of solder paste; placing electronic components onto the printed circuit board such that contacts of the electronic components are aligned with corresponding contact pads of the printed circuit board; and reflow soldering the electronic components to the printed circuit board.

The invention relates to a method (20) for producing an electric circuit (2) in which a circuit carrier (4) comprising a first contact surface (14) and a second contact surface (16) is provided. An insulating body (26) is placed on the circuit carrier (4), wherein the insulating body (26) at least partially covers the first contact surface (14) and the second contact surface (16), and the insulating body (26) comprises a recess (34) in the region of both contact surfaces (14, 16). A flowable electro-conductive medium (44) is introduced into the insulating body (26). The invention also relates to an electric circuit (2) and to a further method (60) for producing an electric circuit (2).

An improved solder column, having a solder core comprising a solder core material, an exoskeleton sleeve structure surrounding at least a majority of an outside surface of the solder core and comprising a plurality of wires woven together to form a mesh, and a plurality of spaces formed in the exoskeleton between the plurality of wires. The exoskeleton sleeve can be configured such that the exoskeleton sleeve will support the solder core so as to prevent a collapse of the solder core at temperatures exceeding a liquidus temperature of the solder core. Optionally, each of the plurality of spaces can have a width and a height that is at least as large as a width of the wire adjacent to the space, and the spaces can be configured to provide additional flexibility to the solder column.

A semiconductor package substrate includes a composite and stacked vertical interconnect on a land side of the substrate. The composite and stacked vertical interconnect includes a smaller contact end against the semiconductor package substrate, and a larger contact end for board mounting.

An electronic component package includes a substrate having an upper surface. Traces on the upper surface of the substrate extend in a longitudinal direction. The traces have a first latitudinal width in a latitudinal direction, the latitudinal direction being perpendicular to the longitudinal direction. Rectangular copper pillars are attached to bond pads of an electronic component, the copper pillars having a longitudinal length and a latitudinal second width. The latitudinal second width of the copper pillars is equal to and aligned with the first latitudinal width of the traces. Further, the longitudinal length of the copper pillars is parallel with the longitudinal direction of the trace and equal to the length of the bond pads. The copper pillars are mounted to the traces with solder joints.

A circuit board structure includes a build-up structure, a graphene layer disposed on the build-up structure, and at least one conductive pillar disposed on the graphene layer, the graphene layer includes an oxidized area not covered by the at least one conductive pillar and a non-oxidized area covered by the at least one conductive pillar, and the at least one conductive pillar is electrically connected to the build-up structure via the non-oxidized area.

A method for manufacturing a chip component includes forming an element, which includes a plurality of element parts, on a substrate. A plurality of fuses are formed, for disconnectably connecting each of the plurality of element parts to an external connection electrode. The external connection electrode, which is arranged to provide external connection for the element, is formed by electroless plating on the substrate.

The invention relates to a contact bump connection (24) and to a method for producing a contact bump connection between an electronic component being provided with at least one terminal face (11) and a contact substrate (26) being contacted with the component and having at least one second terminal face (25), wherein the first terminal face is provided with a contact bump (10), which has a raised edge (15) and has at least one displacement pin (16) in a displacement compartment (18) being surrounded by the raised edge and being open towards a head end of the contact bump, and wherein, in a contact region (31) with the first terminal face, the second terminal face has a contact bead (30), which is formed by displacement of a contact material (29) of the second terminal face into the displacement compartment and which surrounds the displacement pin, said contact bead having a bead crown (33) which is oriented to a bottom (17) of the displacement compartment and is raised relative to a level contact surface (32) of the second terminal face surrounding the contact region.

A stacked electronic structure comprises: a substrate and a magnetic device, wherein a plurality of electronic devices and a plurality of conductive pillars are disposed on and electrically connected to the substrate, wherein a molding body encapsulates the plurality of electronic devices, wherein the magnetic device is disposed over the top surface of the molding body and the plurality of conductive pillars, wherein a first terminal of the magnetic device is disposed over and electrically connected to a first conductive pillar and a second terminal of the magnetic device is disposed over and electrically connected to a second conductive pillar without using any substrate.