A semiconductor power device including a base plate; an input lead; an output lead; a field effect transistor (FET) power die disposed over the base plate, wherein the FET power die includes a set of source fingers, a set of drain fingers, and a set of gate fingers disposed directly over an active region, wherein the gate fingers are configured to receive an input signal from the input lead, and wherein the FET power die is configured to process the input signal to generate an output signal at the drain fingers for routing to the output lead; and electrical conductors (wirebonds or ribbons) bonded to the source and/or drain directly over the active region of the FET power die. The electrical conductors produce additional thermal paths between the active region and the base plate for thermal management of the FET power die.

Circuit-Under-Pad (CUP) device topologies for high current lateral GaN power transistors comprise first and second levels of on-chip metallization M1 and M2; M1 defines source, drain and gate finger electrodes of a plurality of sections of a multi-section transistor and a gate bus; M2 defines an overlying contact structure comprising a drain pad and source pads extending over active regions of each section. The drain and source pads of M2 are interconnected by conductive micro-vias to respective underlying drain and source finger electrodes of M1. The pad structure and the micro-via interconnections are configured to reduce current density in self-supported widths of source and drain finger electrodes, i.e. to optimize a maximum current density for each section. For reduced gate loop inductance, part of each source pad is routed over the gate bus. Proposed CUP device structures provide for higher current carrying capability and reduced drain-source resistance.

A semiconductor device includes an integrated circuit that is disposed at a first face side of a semiconductor substrate, the semiconductor substrate having a first face and a second face, the second face opposing the first face, the semiconductor substrate having a through hole from the first face to the second face; an external connection terminal that is disposed at the first face side; a conductive portion that is disposed in the through hole, the conductive portion being electrically connected to the external connection terminal; and an electronic element that is disposed at a second face side.

Implementations of semiconductor devices may include: a first layer with a plurality of cells, each cell having a drain finger, a source finger and a gate ring; a second layer having a drain pad and a source pad, the drain pad having a width and a source pad having a width substantially the same as the drain pad; wherein a width of each drain finger of the first layer is wider than a width of each source finger of the first layer; and wherein each drain pad is coupled to each drain finger through a first contact and the source pad is coupled to each source finger through a second contact, where a width of the first contact is wider than a width of the second contact.

A semiconductor device includes a heterojunction bipolar transistor and a bump. The heterojunction bipolar transistor (HBT) includes a plurality of unit transistors. The bump is electrically connected to emitters of the plurality of unit transistors through respective overlying conductor filled via openings that overlap in a plan view with a width portion of the bump. The semiconductor device reduces heat resistance in an HBT cell by satisfying two conditions, the first of which is related to specific sizing and positioning of a width portion of the overlying via opening relative to the width portion of the bump, and the second of which is related to positioning the base electrode entirely within a specific region of the width portion of the overlapping overlying via opening.

A semiconductor device includes a silicon carbide body including a transistor cell region and an idle region. The transistor cell region includes transistor cells. The idle region is devoid of transistor cells. The idle region includes a transition region between the transistor cell region and a side surface of the silicon carbide body, a gate pad region, and a diode structure comprising at least one of a merged pin Schottky diode structure or a merged pin heterojunction diode structure in at least one of the transition region or the gate pad region.

A semiconductor package with an embedded capacitor and corresponding manufacturing methods are described. The semiconductor package with the embedded capacitor includes a semiconductor die having a first metal layer extending across at least a portion of a first side of the semiconductor die and a package structure formed on the first side of the semiconductor die. A first electrical conductor of the embedded capacitor is formed in the first metal layer of the semiconductor die. The package structure includes a second metal layer that has formed therein a second electrical conductor of the embedded capacitor. A dielectric of the embedded capacitor is positioned within either the semiconductor die or the package structure of the semiconductor package to isolate the first electrical conductor from the second electrical conductor of the embedded capacitor.

A method for manufacturing a semiconductor device includes forming semiconductor devices from a semiconductor wafer and identifying a position of the semiconductor device in the semiconductor wafer, wherein the forming the semiconductor devices includes forming a first repeating pattern including i semiconductor devices each having a unique pattern, forming a second repeating pattern including j semiconductor devices each having a unique pattern, defining semiconductor devices on the semiconductor wafer such that each of the k semiconductor devices has a unique pattern based on the first and second repeating patterns, and grinding a backside of the semiconductor wafer, wherein each unique pattern of the k semiconductor devices is composed of a combination of the unique patterns of the first and second repeating patterns, wherein the position of the semiconductor device is identified based on the unique patterns of the first and second repeating patterns and an angle of a grinding mark.

The present disclosure provides a semiconductor structure. The semiconductor structure includes a semiconductor substrate, a target layer, a plurality of metal pads, a plurality of conductive lines, a plurality of conductive plugs, an isolating liner, and a plurality of metal contacts. The semiconductor substrate has a front surface, a rear surface opposite to the front surface, and an implanted region connected to the rear surface. The target layer is disposed over the front surface. The metal pads are disposed over the target layer. The plurality of conductive lines are disposed within the semiconductor substrate and the target layer and connected to the metal pads. The conductive plugs are disposed in the implanted region. The isolating liner encircles the conductive plugs. The metal contacts are disposed over the conductive lines and the conductive plugs.

Some embodiments relate to a semiconductor device. The semiconductor device includes a layer disposed over a substrate. A conductive body extends through the layer. A plurality of bar or pillar structures are spaced apart from one another and laterally surround the conductive body. The plurality of bar or pillar structures are generally concentric around the conductive body.