Provided is a chip stack structure including a passivation layer, a plurality of conductive pillars passing through the passivation layer, a buffer chip located on the passivation layer, a plurality of core chips located on the buffer chip and stacked in a vertical direction, and a first molding layer located on the passivation layer and surrounding the buffer chip and the plurality of core chips, wherein an area of an upper surface of the passivation layer is greater than an area of a lower surface of the buffer chip.

A nitride-based semiconductor circuit including a first semiconductor substrate, a second semiconductor substrate, a nitride-based heterostructure, connectors, a first patterned conductive layer, a second patterned conductive layer, and connecting vias is provided. The second substrate is disposed on the first substrate. The first substrate has first dopants, and the second substrate has second dopants, which is different from the first dopants, and a pn junction is formed between the first substrate and the second substrate. The nitride-based heterostructure is disposed on the second substrate. The connectors are disposed on the nitride-based heterostructure. The first and second patterned conductive layers are disposed on the connectors. The connecting vias include a first interconnection and a second interconnection. The first interconnection electrically connects the first substrate to one of the connectors. The second interconnection electrically connects the second substrate to another one of the connectors.

A method is provided for fabricating a semiconductor wafer having a device side, a back side opposite the device side and an outer periphery edge. Suitably, the method includes: forming a top conducting layer on the device side of the semiconductor wafer; forming a passivation layer over the top conducting layer, the passivation layer being formed so as not to extend to the outer periphery edge of the semiconductor wafer; and forming a protective layer over the passivation layer, the protective layer being spin coated over the passivation layer so as to have a smooth top surface at least in a region proximate to the outer periphery edge of the semiconductor wafer.

A semiconductor device includes a dielectric interposer, a first RDL, a second RDL, and a plurality of conductive structures. The dielectric interposer has a first surface and a second surface opposite to the first surface. The first RDL is disposed over the first surface of the dielectric interposer. The second RDL is disposed over the second surface of the dielectric interposer. The conductive structures are disposed through the dielectric interposer and directly contact the dielectric interposer. The conductive structures are electrically connected to the first RDL and the second RDL. Each of the conductive structures has a tapered profile. A minimum width of each of the conductive structures is proximal to the first RDL, and a maximum width of each of the conductive structures is proximal to the second RDL.

A method of manufacturing a semiconductor package includes: forming through-vias extending from a front side of a semiconductor substrate into the substrate; forming, on the front side of the semiconductor substrate, a circuit structure including a wiring structure electrically connected to the through-vias; removing a portion of the semiconductor substrate so that at least a portion of each of the through-vias protrudes to a rear side of the semiconductor substrate; forming a passivation layer covering the protruding portion of each of the through-vias; forming trenches recessed along a periphery of a corresponding one of the through-vias; removing a portion of the passivation layer so that one end of each of the through-vias is exposed to the upper surface of the passivation layer; and forming backside pads including a dam structure in each of the trenches, the dam structure being spaced apart from the corresponding one of the through-vias.

Disclosed is a stacked electronic device including a first and second bonded structure. The first bonded structure includes a first and second semiconductor element, each having a semiconductor region, a front side on one side of the semiconductor region including active circuitry, and a back side opposite the front side. The front side of the first semiconductor element is bonded and electrically connected to the front side of the second semiconductor element. The second bonded structure includes a third and fourth semiconductor element, which can include similar components to the first and second semiconductor elements. The front side of the third semiconductor element is bonded and electrically connected to the front side of the fourth semiconductor element. The back side of the second semiconductor element is bonded and electrically connected to the back side of the third semiconductor element.

A semiconductor device includes a first die including a first stack of layers in a first region on a backside of the first die and a second stack of layers in a second region on the backside of the first die. The first stack of layers has a smaller number of different layers than the second stack of layers. A contact structure is formed in the first region on the backside of the first die. The contact structure extends through the first stack of layers and is configured to conductively connect a first conductive structure on a face side of the first die with a second conductive structure on the backside of the first die. The face side is opposite to the backside.

A power semiconductor device includes a semiconductor structure comprising an active region, an encapsulation material on the semiconductor structure, and a plurality of adhesion features in or on the semiconductor structure along an interface with the encapsulation material. The interface is laterally between the active region and at least one edge of the semiconductor structure. Related devices and fabrication methods are also discussed.

The present invention relates to a semiconductor device including: a semiconductor substrate having: an active region through which a main current flows; and a termination region around the active region; a polyimide film disposed in the active region and the termination region; and a passivation film disposed as a film underlying the polyimide film, wherein the termination region includes, in order from a side of the active region, a breakdown voltage holding region and an outermost peripheral region, the polyimide film is disposed except for a dicing remaining portion of the outermost peripheral region, and the passivation film is disposed, as the underlying film, at least in a region where the polyimide film is disposed.

The glass for covering a semiconductor element contains: in mol %, as a glass composition, SiO.sub.2: 20% to 36%, ZnO: 8% to 40%, B.sub.2O.sub.3: 10% to 24%, Al.sub.2O.sub.3: 10% to 20%, and MgO+CaO: 8% to 22%, in which SiO.sub.2/ZnO is 0.6 or more and less than 3.3 in terms of a molar ratio, and a lead component is substantially not contained.