A molding compound comprising a resin, a filler, and a carbon nano-tube dispersion is disclosed. The carbon nano-tube dispersion achieves a low average agglomeration size in the molding compound thereby providing desirable electro-mechanical properties and laser marking compatibility. A shallow laser mark may be formed in a mold cap with a maximum depth of less than 10 microns.

To enhance reliability in assembling a semiconductor device. There is provided a wiring substrate including a target mark, which is not provided on an extension line of a dicing region provided between a first semiconductor device region and a second semiconductor device region but is provided between the extension line of the dicing region and a first imaginary extension line of a first outermost peripheral land row and between the extension line of the dicing region and a second imaginary extension line of a second outermost peripheral land row. Furthermore, after mounting a semiconductor chip, wire bonding is performed, resin sealing is performed and a solder ball is mounted. After that, the dicing region is specified on the basis of the target mark, and the wiring substrate is cut along the dicing region.

The semiconductor device includes a wiring substrate having a plurality of ball lands formed on a lower surface of a core layer, a solder resist film covering the lower surface of the core layer, a via conductor layer penetrating the core layer and connected to the ball lands, and an upper surface wiring formed on the upper surface of the core layer, the upper surface wiring having one end formed as a bonding land and the other end connected to the via conductor layer. The semiconductor device further includes a semiconductor chip arranged on the wiring substrate, a solder ball connected to the ball lands. The solder resist film has an eliminating portion that exposes the lower surface of the core layer, and the upper surface wiring has a thin-wire portion and a thick-wire portion, and when seen in a plan view, the thick-wire portion overlaps the eliminating portion.

One or more embodiments are directed to semiconductor packages with one or more cantilever pads and methods of making same. In one embodiment a recess is located in a substrate of the package facing the cantilever pad. The cantilever pad includes a conductive pad on which a conductive ball is formed. The cantilever pad is configured to absorb stresses acting on the package.

Various embodiments disclose a molding compound comprising a resin, a filler, and a carbon nano-tube dispersion and methods of forming a package using the molding compound is disclosed. The carbon non-tube dispersion has a number of carbon nano-tubes with surfaces that are chemically modified by a functional group to chemically bridge the surfaces of the carbon nano-tubes and the resin, improving adhesion between the carbon nano-tubes and the resin and reducing agglomeration between various ones of the carbon nano-tubes. The carbon nano-tube dispersion achieves a low average agglomeration size in the molding compound thereby providing desirable electro-mechanical properties and laser marking compatibility. A shallow laser mark may be formed in a mold cap with a maximum depth of less than about 10 microns. Other apparatuses and methods are disclosed.

A semiconductor device includes a composite chip mounted over the a wiring substrate, the composite chip including a first area, a second area that is provided independently from the first area, and a third area including a first material between the first and second areas. the first area including a first circuit formed in the first area, and the second area including a second circuit formed in the second area. The first area is spaced apart from the second area by the first material.

One or more embodiments are directed to semiconductor packages with one or more cantilever pads. In one embodiment a recess is located in a substrate of the package facing the cantilever pad. The cantilever pad includes a conductive pad on which a conductive ball is formed. The cantilever pad is configured to absorb stresses acting on the package.

A process for forming land grid array semiconductor packages includes a leadframe that is supported by a substrate comprising mold compound. In some embodiments, at least one die is electrically coupled to the leadframe by bondwires. The package comprises a second mold compound to act as an encapsulant. An apparatus for forming a land grid array semiconductor package includes means for molding a leadframe, assembling thereon at least one semiconductor device, applying a second mold, and singulating to form individual devices. A land grid array package comprises a leadframe, a substrate for supporting the leadframe, at least one semiconductor device and a mold compound.

A semiconductor package may be provided. A semiconductor package may include a substrate. The semiconductor package may include a first semiconductor chip and a second semiconductor chip which are disposed adjacent to each other over a first surface of the substrate. The semiconductor package may include first bonding wires which electrically couple the first semiconductor chip and the substrate. The semiconductor package may include an insulation adhesive which is interposed between the second semiconductor chip and the substrate. The first bonding wires may be disposed to pass through the insulation adhesive and electrically couple the first semiconductor chip and the substrate.

A process for forming land grid array semiconductor packages includes a leadframe that is supported by a substrate comprising mold compound. In some embodiments, at least one die is electrically coupled to the leadframe by bondwires. The package comprises a second mold compound to act as an encapsulant. An apparatus for forming a land grid array semiconductor package includes means for molding a leadframe, assembling thereon at least one semiconductor device, applying a second mold, and singulating to form individual devices. A land grid array package comprises a leadframe, a substrate for supporting the leadframe, at least one semiconductor device and a mold compound.