A semiconductor device includes a first substrate, a second substrate spaced apart from the first substrate in a first direction, a first metal layer on the first substrate, a second metal layer on the first substrate and spaced apart from the first metal layer in a second direction, a first semiconductor element, and a second semiconductor element. The second substrate includes a main wiring and a signal wiring. The first semiconductor element includes a first electrode on the first metal layer, a second electrode connected to the main wiring, and a first gate electrode connected to the signal wiring. The second semiconductor element includes a third electrode on the second metal layer, a fourth electrode connected to the main wiring, and a second gate electrode connected to the signal wiring. During operation, current flows in wiring layers of the main wiring in opposite directions.

The semiconductor device according to the present disclosure has features (1) to (3) below. The feature (1) is that “a lower surface of an on-chip bonding material has a shape matching a surface shape of a main current wiring connection region in plan view”. The feature (2) is that “an emitter sense wiring is directly connected to a side surface of the main current wiring connection region”. The feature (3) is that “an IGBT chip has an ineffective region in which the IGBT does not function in a region below an emitter sense pad and the emitter sense wiring”.

The present disclosure provides a semiconductor package structure and a method of manufacturing the same. The semiconductor package structure includes a substrate, a first electronic component, an interlayer, a third electronic component and an encapsulant. The first electronic component is disposed on the substrate. The first electronic component has an upper surface and a lateral surface and a first edge between the upper surface and the lateral surface. The interlayer is on the upper surface of the first electronic component. The third electronic component is attached to the upper surface of the first electronic component via the interlayer. The encapsulant encapsulates the first electronic component and the interlayer. The interlayer does not contact the lateral surface of the first electronic component.

The present disclosure relates to a thermally enhanced package, which includes a carrier, a thinned die over the carrier, a mold compound, and a heat extractor. The thinned die includes a device layer over the carrier and a dielectric layer over the device layer. The mold compound resides over the carrier, surrounds the thinned die, and extends beyond a top surface of the thinned die to define an opening within the mold compound and over the thinned die. The top surface of the thinned die is at a bottom of the opening. At least a portion of the heat extractor is inserted into the opening and in thermal contact with the thinned die. Herein the heat extractor is formed of a metal or an alloy.

A semiconductor device includes a first lead portion and a second lead portion spaced from each other in a first direction. A semiconductor chip is mounted to the first lead portion. A first connector has a first portion contacting a second electrode on the chip and a second portion connected to the second lead portion. A second connector has third portion that contacts the second electrode, but at a position further away than the first portion, and a fourth portion connected to the second portion. At least a part of the second connector overlaps a part of the first connector between the first lead portion and the second lead portion.

A power semiconductor module includes a plurality of self-arc-extinguishing semiconductor elements, a printed wiring board, a plurality of conductive joining members, and a plurality of conductive gate wires. The printed wiring board includes an insulating substrate, a source conductive pattern, and a gate conductive pattern. The plurality of self-arc-extinguishing semiconductor elements each include a source electrode and a gate electrode. The source electrodes are joined to the source conductive pattern by means of the plurality of conductive joining members. The plurality of conductive gate wires connect the gate electrodes and the gate conductive pattern.

A semiconductor device includes first and second semiconductor elements and first and second conductive members. A first electrode on the first semiconductor element is bonded to a first stack part of the first conductive member by a first bonding layer. A second electrode on the second semiconductor element is bonded to a second stack part of the second conductive member by a second bonding layer. A first joint part of the first conductive member is bonded to a second joint part of the second conductive member by an intermediate bonding layer. A first surface of the first joint part facing the second joint part, a side surface of the first joint part continuous from the first surface, a second surface of the second joint part facing the first joint part, and a side surface of the second joint part continuous from the second surface are covered by nickel layers.

The present disclosure is directed to a method of manufacturing semiconductor devices that includes providing a substrate such as a leadframe having a non-etched adhesion promoter, NEAP layer over the die mounting surface and attaching thereon a semiconductor die having an attachment surface including a first and a second die areas that are wettable by electrically conductive solder material. The NEAP layer is selectively removed, e.g., via laser ablation, from the first substrate area and the second substrate area of the die mounting surface of the substrate. The first substrate area and the second substrate area of the substrate having complementary shapes with respect to the first and second die areas of the semiconductor die. Electrically conductive solder material is dispensed on the first and second substrate areas of the substrate. A semiconductor die is flipped onto the substrate with the first die area and the second die area aligned with the first substrate area and the second substrate area of the substrate having the solder material dispensed thereon. The electrically conductive solder material thus provides electrical coupling of: the first die area and the first substrate area, and the second die area and the second substrate area.

The present disclosure provides a method for manufacturing a double-sided cooling type power module including separately patterning a bonding material on a base film into two regions, positioning a semiconductor chip on the patterned bonding material, transferring the patterned bonding material to one surface of the semiconductor chip by pressurizing the semiconductor chip, positioning the bonding material of the semiconductor chip on an upper electrode layer formed on an upper substrate to be in contact with the upper electrode layer, and sintering an upper bonding layer by pressurizing and heating the semiconductor chip. According to the present disclosure, it is possible to separately dispose the bonding material on each of gate and source electrode parts on an upper portion of the chip even without protrusion to directly bond the chip and the substrate.

A semiconductor device includes a first lead portion and a second lead portion spaced from each other in a first direction. A semiconductor chip is mounted to the first lead portion. A first connector has a first portion contacting a second electrode on the chip and a second portion connected to the second lead portion. A second connector has third portion that contacts the second electrode, but at a position further away than the first portion, and a fourth portion connected to the second portion. At least a part of the second connector overlaps a part of the first connector between the first lead portion and the second lead portion.