An SiC semiconductor device includes an SiC semiconductor layer including an SiC monocrystal that is constituted of a hexagonal crystal and having a first main surface as a device surface facing a c-plane of the SiC monocrystal and has an off angle inclined with respect to the c-plane, a second main surface at a side opposite to the first main surface, and a side surface facing an a-plane of the SiC monocrystal and has an angle less than the off angle with respect to a normal to the first main surface when the normal is 0°.

A semiconductor device includes a semiconductor element, which has a protective film having an opening that exposes a part of a source electrode and disposed/provided to position an end portion thereof on the source electrode. A rewiring layer has wiring that is connected to the source electrode and to a conductive connecting member, and an insulator that covers a part of the source wiring. The insulator includes: an insulating film having (a) an opening for exposing a part of the source wiring, and (b) an end portion of the opening provided in a facing region of the opening; and an insulating film having (c) (i) an opening for exposing a part of the source wiring having a solder arranged therein and (ii) a connecting member arranged therein.

Devices, methods and techniques are disclosed to suppress electrical discharge and breakdown in insulating or encapsulation material(s) applied to solid-state devices. In one example aspect, a multi-layer encapsulation film includes a first layer of a first dielectric material and a second layer of a second dielectric material. An interface between the first layer and the second layer is configured to include molecular bonds to prevent charge carriers from crossing between the first layer and the second layer. The multi-layer encapsulation configuration is structured to allow an electrical contact and a substrate of the solid-state device to be at least partially surrounded by the multi-layer encapsulation configuration.

A multi-chip assembly includes: a first power transistor die having a source terminal facing a first direction and a drain terminal facing a second direction opposite the first direction; and a second power transistor die having a drain terminal facing the first direction, and a source terminal facing the second direction. A dielectric material occupies a gap between the first power transistor die and the second power transistor die, and secures the first power transistor die and the second power transistor die to one another. A metallization connects the source terminal of the first power transistor die to the drain terminal of the second power transistor die at a same side of the multi-chip assembly. The gap occupied by the dielectric material is less than 70 μm. Corresponding methods of producing multi-chip assemblies are also described.

A semiconductor package is provided in which a first insulating layer includes a first recess spaced apart from a first pad in a first direction, and a second insulating layer includes a second recess spaced apart from a second pad in the first direction and overlapping at least a portion of the first recess in a second direction, perpendicular to the first direction, to provide an air gap together with the first recess. The semiconductor package further includes a first bonding surface defined by the first and second insulating layers contacting each other on one side of the air gap, adjacent to the first and second pads, and a second bonding surface defined by the first and second insulating layers contacting each other on another side of the air gap, opposite to the one side.

The present application discloses a method for fabricating a semiconductor device. The method for fabricating a semiconductor device includes providing a substrate, forming a pad structure above the substrate, and forming a top groove on a top surface of the pad structure.

A three-dimensional (3D) integrated circuit (IC) is provided. In some embodiments, a second IC die is bonded to a first IC die. A seal-ring structure is arranged in a peripheral region of the 3D IC in the first IC die and the second IC die. The seal-ring structure extends from a first semiconductor substrate of the first IC die to a second semiconductor substrate of the second IC die. A plurality of through silicon via (TSV) coupling structures is arranged at the peripheral region of the 3D IC along an inner perimeter of the seal-ring structure closer to the 3D IC than the seal-ring structure. The plurality of TSV coupling structures respectively comprises a TSV disposed in the second semiconductor substrate and electrically coupling to the 3D IC through a stack of TSV wiring layers and inter-wire vias.

Reliable plasma dicing of wafers to singulate it into individual dies is disclosed. Laser processing is employed to form mask openings in a passivation stack of a processed wafer. The patterned passivation stack serves as a plasma dicing mask for plasma dicing the wafer. The sidewalls of the mask openings may be flat or vertical sidewalls. In other cases, the sidewalls of the mask openings are slanted or chamfered sidewalls. The plasma dices the wafer using first and second plasma etch steps. The first plasma etch step etches to form scalloped sidewalls on the first portion of the die and the second plasma step etches to form flat or vertical sidewalls on a second portion of the die. The second portion of the die is the lower portion of the substrate or wafer. This prevents backside notching to improve reliability.

A wafer chip scale package (WCSP) includes a substrate including a semiconductor surface including circuitry electrically connected to die bond pads exposed by a passivation layer, and a top dielectric layer over the passivation layer. A dielectric layer bounded (DLB) cavity formed in the top dielectric layer includes a first cavity being a center through-cavity bounded by a second cavity being a partial through-cavity, the DLB cavity is lined with a seed layer. A capping dielectric layer that covers the DLB cavity except for an aperture over the first cavity. A cavity metal that is generally configured as an integral structure of continuous metal material having no interfaces is for filling the DLB cavity to form a metal filled cavity including over the aperture that has an electrical connection to the die bond pads. A solder ball over the cavity metal is positioned over the aperture.

A semiconductor device includes a semiconductor layer that has a main surface, a main surface electrode that is arranged at the main surface, an insulating film that partially covers the main surface electrode such as to expose a portion of the main surface electrode, a mold layer that covers the insulating film such as to expose the main surface electrode, and a pad electrode that is arranged on the main surface electrode such as to be electrically connected to the main surface electrode.