A semiconductor package system includes a substrate, a first and a second semiconductor package, a first thermal conductive layer, a first passive device, and a heat radiation structure. The first and second semiconductor package and first passive device may be mounted on a top surface of the substrate. The first semiconductor package may include a first semiconductor chip that includes a plurality of logic circuits. The first thermal conductive layer may be on the first semiconductor package. The heat radiation structure may be on the first thermal conductive layer, the second semiconductor package, and the first passive device. The heat radiation structure may include a first bottom surface physically contacting the first thermal conductive layer, and a second bottom surface at a higher level than that of the first bottom surface. The second bottom surface may be on the second semiconductor package and/or the first passive device.

A semiconductor package system includes a substrate, a first and a second semiconductor package, a first thermal conductive layer, a first passive device, and a heat radiation structure. The first and second semiconductor package and first passive device may be mounted on a top surface of the substrate. The first semiconductor package may include a first semiconductor chip that includes a plurality of logic circuits. The first thermal conductive layer may be on the first semiconductor package. The heat radiation structure may be on the first thermal conductive layer, the second semiconductor package, and the first passive device. The heat radiation structure may include a first bottom surface physically contacting the first thermal conductive layer, and a second bottom surface at a higher level than that of the first bottom surface. The second bottom surface may be on the second semiconductor package and/or the first passive device.

The present invention provides an anisotropic electrically conductive film with a structure, in which electrically conductive particles are disposed at lattice points of a planar lattice pattern in an electrically insulating adhesive base layer. A proportion of the lattice points, at which no electrically conductive particle is disposed, with respect to all the lattice points of the planar lattice pattern assumed as a reference region, is less than 20%. A proportion of the lattice points, at which plural electrically conductive particles are disposed in an aggregated state, with respect to all the lattice points of the planar lattice pattern, is not greater than 15%. A sum of omission of the electrically conductive particle and an aggregation of the electrically conductive particles is less than 25%.

A first electronic element is disclosed, which includes: a first substrate having a first surface; a first electrode pad disposed on the first surface, wherein the first electrode pad has a second surface away from the first substrate; and an insulating layer disposed on the first surface, wherein the insulating layer includes an opening, the opening is disposed correspondingly to the first electrode pad, and the opening overlaps the first electrode pad in a normal direction of the first surface, wherein the insulating layer has a third surface away from the first substrate, a distance between the third surface and the second surface in the normal direction of the first surface is defined as a first distance, and the first distance is greater than 0 m and less than or equal to 14 m. In addition, the disclosure further provides an electronic device including the first electronic element.

A device comprising a connecting plate and a circuit element is disclosed. The circuit element is electrically coupled to the connecting plate through a solder connection including a plurality of solder balls disposed between the circuit element and the connecting plate. An underfill layer is formed between the circuit element and the connecting plate and configured to provide bonding between the circuit element and the connecting plate. The solder connection includes a first solder area with a first solder ball density and a second solder area with a second solder ball density. The first solder ball density is less than the second solder ball density. The underfill layer includes a bonding material continuously disposed in the second solder area of the solder connection.

A device comprising a connecting plate and a circuit element is disclosed. The circuit element is electrically coupled to the connecting plate through a solder connection including a plurality of solder balls disposed between the circuit element and the connecting plate. An underfill layer is formed between the circuit element and the connecting plate and configured to provide bonding between the circuit element and the connecting plate. The solder connection includes a first solder area with a first solder ball density and a second solder area with a second solder ball density. The first solder ball density is less than the second solder ball density. The underfill layer includes a bonding material continuously disposed in the second solder area of the solder connection.

There is provided a paste composition using copper fine particles that are capable of exhibiting conductivity after low-temperature sintering, which themselves are less oxidized, and that can be produced with a high yield ratio. A paste composition contains: (A) copper fine particles having a thickness or minor axis of 10 to 500 nm and coated with amino alcohol represented by the chemical formula (1) and (B) an organic solvent.

A method of manufacturing an electronic device comprising the steps of: preparing a substrate comprising an electrically conductive layer; applying a conductive paste on the electrically conductive layer; mounting an electrical component on the applied conductive paste; heating the conductive paste to bond the electrically conductive layer and the electrical component, wherein the conductive paste comprises 100 parts by weight of the metal powder, 5 to 20 parts by weight of a solvent, and 0.05 to 3 parts by weight of a polymer, wherein the polymer comprises a first polymer and a second polymer, wherein the molecular weight (Mw) of the first polymer is 5,000 to 95,000, and the molecular weight (Mw) of the second polymer is 100,000 to 300,000.

A power semiconductor element and a support member are stacked with an intermediate structure being interposed between the power semiconductor element and the support member. The intermediate structure includes a first metal paste layer and at least one first penetrating member. The first metal paste layer contains a plurality of first metal particles. The at least one first penetrating member penetrates the first metal paste layer. At least one first vibrator attached to the at least one first penetrating member penetrating the first metal paste layer is vibrated. The first metal paste layer is heated so that the plurality of first metal particles are sintered or fused.

A power semiconductor element and a support member are stacked with an intermediate structure being interposed between the power semiconductor element and the support member. The intermediate structure includes a first metal paste layer and at least one first penetrating member. The first metal paste layer contains a plurality of first metal particles. The at least one first penetrating member penetrates the first metal paste layer. At least one first vibrator attached to the at least one first penetrating member penetrating the first metal paste layer is vibrated. The first metal paste layer is heated so that the plurality of first metal particles are sintered or fused.