A semiconductor device includes a semiconductor die attached to a substrate and a metal clip attached to a side of the semiconductor die facing away from the substrate by a soldered joint. The metal clip has a plurality of slots dimensioned so as to take up at least 10% of a solder paste reflowed to form the soldered joint. Corresponding methods of production are also described.

A semiconductor module includes first to fourth semiconductor elements, each having an upper-surface electrode and a lower-surface electrode, first to fourth conductive layers, each extending in a first direction and being independently disposed side by side in a second direction orthogonal to the first direction, and an output terminal connected to the second and third conductive layers. The lower-surface electrodes of each of the first to fourth semiconductor elements are respectively conductively connected to the first to fourth conductive layers. The third conductive layer and the fourth conductive layer are disposed between the first conductive layer and the second conductive layer and are connected to the output terminal to have an equal potential.

A clip for a semiconductor package and a semiconductor having a clip is disclosed. In one example, the clip includes a first planar portion, a plurality of first pillars, and a plurality of first solder balls. Each first pillar of the plurality of first pillars is coupled to the first planar portion. Each first solder ball of the plurality of first solder balls is coupled to a corresponding first pillar of the plurality of first pillars.

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 semiconductor device has a leadframe and a first electrical component including a first surface disposed on the leadframe. A first clip bond is disposed over a second surface of the first electrical component. The first clip bond extends vertically through the semiconductor device. The first clip bond has a vertical member, horizontal member connected to the vertical member, die contact integrated with the horizontal member, and clip foot extending from the vertical member. A second electrical component has a first surface disposed on the first clip bond. A second clip bond is disposed over a second surface of the second electrical component opposite the first surface of the second electrical component. An encapsulant is deposited around the first electrical component and first clip bond. A second electrical component is disposed over the encapsulant. The clip foot is exposed from the encapsulant.

A semiconductor device has a leadframe and a first electrical component disposed over the leadframe. A clip bond is disposed over the first electrical component. The clip bond has a plurality of recesses each having a different depth. A first recess is proximate to a first distal end of the first electrical component, and a second recess is proximate to a second distal end of the first electrical component opposite the first distal end of the first electrical component. A depth of the first recess is different from a depth of the second recess. A third recess is over a surface of the first electrical component. A depth of the third recess is different from the depth of the first recess and the depth of the second recess. A second electrical component is disposed over the leadframe. The clip bond extends over the second electrical component.

An embodiment related to a package is disclosed. The package includes a component mounted to a die attach region on a package substrate. A passive component with first and second passive component terminals is vertically attached to the package substrate. An encapsulant is disposed over the package substrate to encapsulate the package. In one embodiment, an external component is stacked above the encapsulant and is electrically coupled to the encapsulated package.

Techniques are disclosed herein for forming a dual flat no-leads semiconductor package. The techniques begin with a package assembly that includes multiple non-singulated packages. The semiconductor package assembly includes a lead frame assembly having dies coupled thereto. A mold encapsulation covers at least portions of the dies and exposes a plurality of leads. A first cutting step exposes sidewalls of leads of the lead frame. An electroplating step deposits a plating on the exposed leads. A second cutting step cuts through the mold encapsulation aligned with the step cut sidewalls. A third cutting step perpendicular to the step cuts and is made through the lead frame and mold encapsulation to singulate the dies into individual packages.

A furcated clip includes a removable collar, and an arrangement of stems attached to the removable collar. The stems are configured for contacting bond pads of a semiconductor die and connecting the bond pads to leadframe posts of a leadframe structure.

A semiconductor device includes a semiconductor element, a first lead supporting the semiconductor element, a second lead separated from the first lead, and a connection lead electrically connecting the semiconductor element to the second lead. The connection lead has an end portion soldered to the second lead. This connection-lead end portion has a first surface facing the semiconductor element and a second surface opposite to the first surface. The second lead is formed with a recess that is open toward the semiconductor element. The recess has a side surface facing the second surface of the connection-lead end portion. A solder contact area of the second surface of the connection-lead end portion is larger than a solder contact area of the first surface of the connection-lead end portion.