An apparatus, and methods therefor, relates generally to an integrated circuit package. In such an apparatus, a platform substrate has a copper pad. An integrated circuit die is coupled to the platform substrate. A wire bond wire couples a contact of the integrated circuit die and the copper pad. A first end of the wire bond wire is ball bonded with a ball bond for direct contact with an upper surface of the copper pad. A second end of the wire bond wire is stitch bonded with a stitch bond to the contact.

The present disclosure provides a semiconductor package. The semiconductor package includes a carrier member, a plurality of inductors and a memory chip. The carrier member includes a first surface, a second surface and a centrally-located opening. The carrier member also includes a plurality of conductive pads on the second surface proximal to the opening. The memory chip is attached to the carrier member in a face-down manner. The memory chip includes a plurality of bidirectional and unidirectional signal-transmission pins electrically coupled to the inductors. The memory chip also includes a plurality of bonding pads. A plurality of bonding wires, passing through the opening, electrically connect the bonding pads on the memory chip to the conductive pads on the carrier member. A first insulative structure substantially encapsulates the memory chip and the inductors. A plurality of solder balls are attached to the second surface of the carrier member.

The present disclosure provides a semiconductor package. The semiconductor package includes a carrier member, a plurality of inductors and a memory chip. The carrier member includes a first surface, a second surface and a centrally-located opening. The carrier member also includes a plurality of conductive pads on the second surface proximal to the opening. The memory chip is attached to the carrier member in a face-down manner. The memory chip includes a plurality of bidirectional and unidirectional signal-transmission pins electrically coupled to the inductors. The memory chip also includes a plurality of bonding pads. A plurality of bonding wires, passing through the opening, electrically connect the bonding pads on the memory chip to the conductive pads on the carrier member. A first insulative structure substantially encapsulates the memory chip and the inductors. A plurality of solder balls are attached to the second surface of the carrier member.

Disclosed is a temporary protective film for semiconductor sealing molding 10 including a support film 1; and an adhesive layer 2 provided on the support film 1 and containing an acrylic rubber. A solid shear modulus at 200° C. of the temporary protective film for semiconductor sealing molding 10 may be 5.0 MPa or higher.

A light emitting device package includes a first molding member surrounding a heat dissipation frame, a first electrode frame, and a second electrode frame; a first semiconductor light emitting device on the heat dissipation frame and having first and second pads; a second semiconductor light emitting device on the heat dissipation frame and having first and second pads; a wavelength conversion layer on the first and second semiconductor light emitting structures; a first bonding wire connected to the first pad of the first semiconductor light emitting device and the first electrode frame; a second bonding wire connected to the second pad of the second semiconductor light emitting device and the second electrode frame; and an inter-chip bonding wire connecting the second pad of the first semiconductor light emitting device to the first pad of the second semiconductor light emitting device.

A light emitting device package includes a first molding member surrounding a heat dissipation frame, a first electrode frame, and a second electrode frame; a first semiconductor light emitting device on the heat dissipation frame and having first and second pads; a second semiconductor light emitting device on the heat dissipation frame and having first and second pads; a wavelength conversion layer on the first and second semiconductor light emitting structures; a first bonding wire connected to the first pad of the first semiconductor light emitting device and the first electrode frame; a second bonding wire connected to the second pad of the second semiconductor light emitting device and the second electrode frame; and an inter-chip bonding wire connecting the second pad of the first semiconductor light emitting device to the first pad of the second semiconductor light emitting device.

A silicon carbide device includes a silicon carbide substrate, a contact layer including nickel, silicon and aluminum, a barrier layer structure including titanium and tungsten, and a metallization layer including copper. The contact layer is located on the silicon carbide substrate. The contact layer is located between the silicon carbide substrate and at least a part of the barrier layer structure. The barrier layer structure is located between the silicon carbide substrate and the metallization layer.

A semiconductor device is disclosed including a wire bonded die stack where the bond wires skip dies in the die stack to provide bond wires having a long length. In one example, the semiconductor dies are stacked on top of each other with offsets along two orthogonal axes so that the dies include odd numbered dies interspersed and staggered with respect to even numbered dies only one of the axes. Wire bonds may be formed between the odd numbered dies, skipping the even numbered dies, and wire bonds may be formed between the even numbered dies, skipping the odd numbered dies. The long length of the bond wires increases an inductance of the wire bonds relative to parasitic capacitance of the semiconductor dies, thereby increasing signal path bandwidth of the semiconductor device.

The sinter-bonding composition contains sinterable particles containing an electroconductive metal. The average particle diameter of the sinterable particles is 2 μm or less and the proportion of the particles having a particle diameter of 100 nm or less in the sinterable particles is not less than 80% by mass. The sinter-bonding sheet (10) has an adhesive layer made from such a sinter-bonding composition. The dicing tape with a sinter-bonding sheet (X) has such a sinter-bonding sheet (10) and a dicing tape (20). The dicing tape (20) has a lamination structure containing a base material (21) and an adhesive layer (22), and the sinter-bonding sheet (10) is positioned on the adhesive layer (22) of the dicing tape (20).

The sinter-bonding composition contains sinterable particles containing an electroconductive metal. The average particle diameter of the sinterable particles is 2 μm or less and the proportion of the particles having a particle diameter of 100 nm or less in the sinterable particles is not less than 80% by mass. The sinter-bonding sheet (10) has an adhesive layer made from such a sinter-bonding composition. The dicing tape with a sinter-bonding sheet (X) has such a sinter-bonding sheet (10) and a dicing tape (20). The dicing tape (20) has a lamination structure containing a base material (21) and an adhesive layer (22), and the sinter-bonding sheet (10) is positioned on the adhesive layer (22) of the dicing tape (20).