An apparatus and method for providing an artificial standoff to the bottom of leads on a QFN device sufficient to provide a gap that changes the fluid dynamics of solder flow and create a unique capillary effect that drives solder up the of leads of a UN device when it is attached to a printed wiring board (PWB).

The present disclosure discloses a display panel and a method for manufacturing the same, a bonding method, and a display device. The display panel is provided with a bonding area and includes a bonding structure in the bonding area, and the bonding structure is provided with a through hole penetrating along a thickness direction of the bonding structure. The present disclosure helps to improve the bonding efficiency between the display panel and a flexible printed circuit.

In one example, a semiconductor device can comprise a substrate, a device stack, first and second internal interconnects, and an encapsulant. The substrate can comprise a first and second substrate sides opposite each other, a substrate outer sidewall between the first substrate side and the second substrate side, and a substrate inner sidewall defining a cavity between the first substrate side and the second substrate side. The device stack can be in the cavity and can comprise a first electronic device, and a second electronic device stacked on the first electronic device. The first internal interconnect can be coupled to the substrate and the device stack. The encapsulant can cover the substrate inner sidewall and the device stack and can fill the cavity. Other examples and related methods are disclosed herein.

A semiconductor device includes a semiconductor element, a lead frame, a conductive member, a resin composition and a sealing resin. The semiconductor element has an element front surface and an element back surface facing away in a first direction. The semiconductor element is mounted on the lead frame. The conductive member is bonded to the lead frame, electrically connecting the semiconductor element and the lead frame. The resin composition covers a bonded region where the conductive member and lead frame are bonded while exposing part of the element front surface. The sealing resin covers part of the leadframe, the semiconductor element, and the resin composition. The resin composition has a greater bonding strength with the lead frame than a bonding strength between the sealing resin and lead frame and a greater bonding strength with the conductive member than a bonding strength between the sealing resin and conductive member.

A package includes a leadframe having first surface and a second surface opposing the first surface, the leadframe forming a plurality of leads, a first semiconductor die mounted on the first surface of the leadframe and electrically connected to at least one of the plurality of leads, a second semiconductor die mounted on the second surface of the leadframe, wire bonds electrically connecting the second semiconductor die to the leadframe, and mold compound at least partially covering the first semiconductor die, the second semiconductor die and the wire bonds.

An integrated circuit chip is attached to a support that includes first conductive elements. First conductive pads are located on the integrated circuit chip and are electrically coupled to the first conductive elements by conductive wires. The integrated circuit chip further includes a conductive track. A switch circuit is provided to selectively electrically connect each first conductive pad to the conductive track. To test the conductive wires, a group of first conductive pads are connected by their respective switch circuits to the conductive track and current flow between corresponding first conductive elements is measured.

A multifaceted capillary that can be used in a wire-bonding machine to create a multi-segment wire-bond is disclosed. The multifaceted capillary is shaped to apply added pressure and thickness to an outer segment of the multi-segment wire-bond that is closest to the wire loop. The added pressure eliminates a gap under a heel portion of the multi-segment wire-bond and the added thickness increases a mechanical strength of the heel portion. As a result, a pull test of the multi-segment wire-bond may be higher than a single-segment wire-bond and the multi-segment wire-bond may resist cracking, lifting, or breaking.

In examples, a semiconductor package comprises a substrate and multiple columns of semiconductor dies positioned approximately in parallel along a length of the substrate. The package also includes multiple passive components positioned between the multiple columns of semiconductor dies, the multiple passive components angled between 30 and 60 degrees relative to the length of the substrate, a pair of the multiple passive components having a gap therebetween that is configured to permit mold compound flow through capillary action. The package also includes a mold compound covering the substrate, the multiple columns of semiconductor dies, and the multiple passive components.

In examples, a method of manufacturing a semiconductor package comprises providing an array of unsingulated semiconductor packages, the array having a bottom surface and a conductive terminal exposed to the bottom surface, the conductive terminal including a slot configured to receive solder material. The method includes coupling a tape to the array of unsingulated semiconductor packages and applying a first saw blade to the bottom surface of the array to partially saw through a thickness of the array to a depth between two individual, adjacent, unsingulated semiconductor packages in the array of unsingulated semiconductor packages, the first saw blade producing a kerf. The method includes applying a second saw blade into the kerf to fully saw through the thickness of the array and produce a singulated semiconductor package, a width of the second saw blade narrower than the first saw blade. The conductive terminal is exposed to a side surface of the singulated semiconductor package, the side surface including a recessed area having a horizontal depth of no more than 30 microns.

A bonded structure includes a semiconductor element, an electrical conductor and a sintered metal layer. The semiconductor element has an element obverse surface and an element reverse surface spaced apart from each other in a first direction and includes a reverse-surface electrode on the element reverse surface. The electrical conductor has a mount surface facing in a same direction as the element obverse surface and supports the semiconductor element with the mount surface facing the element reverse surface. The sintered metal layer bonds the semiconductor element to the electrical conductor and electrically connects the reverse-surface electrode and the electrical conductor. The mount surface includes a roughened area roughened by a roughening process. The sintered metal layer is formed on the roughened area.