A III-nitride-based semiconductor packaged structure includes a lead frame, an adhesive layer, a III-nitride-based die, an encapsulant, and at least one bonding wire. The lead frame includes a die paddle and a lead. The die paddle has first and second recesses arranged in a top surface of the die paddle. The first recesses are located adjacent to a relatively central region of the top surface. The second recesses are located adjacent to a relatively peripheral region of the top surface. The first recess has a shape different from the second recess from a top-view perspective. The adhesive layer is disposed on the die paddle to fill into the first recesses. The III-nitride-based die is disposed on the adhesive layer. The encapsulant encapsulates the lead frame and the III-nitride-based die. The second recesses are filled with the encapsulant. The bonding wire is encapsulated by the encapsulant.

An LED device capable of emitting electromagnetic radiation ranging from about 200 nm to 365 nm, the device. The device includes a substrate member, the substrate member being selected from sapphire, silicon, quartz, gallium nitride, gallium aluminum nitride, or others. The device has an active region overlying the substrate region, the active region comprising a light emitting spatial region comprising a p-n junction and characterized by a current crowding feature of electrical current provided in the active region. The light emitting spatial region is characterized by about 1 to 10 microns. The device includes an optical structure spatially disposed separate and apart the light emitting spatial region and is configured to facilitate light extraction from the active region.

HEMT having a drain field plate is provided. The drain field plate is formed in the area between the gate and drain of a HEMT. The drain field plate includes a metal pad that has a larger projection area than the drain pad. The drain field plate and semiconductor layer disposed beneath the drain field plate form a metal-semiconductor (M-S) Schottky structure. The capacitance of the M-S Schottky structure generates capacitance in the semiconductor area, which increases the breakdown voltage of the transistor components of the HEMT. A portion of the substrate under the active area may be removed to thereby increase the heat conductivity and reduce the junction temperature of the transistor components of the HEMT.

According to a first aspect of the present disclosure, a semiconductor device is provided. The semiconductor device includes a first transistor, a second transistor, at least one source terminal, at least one gate terminal, at least one drain terminal, a source wire, a gate wire, a drain wire and a support part. The support part includes two first support-part edges and two second support-part edges. Each of the two first support-part edges is parallel to a first direction, and the two first support-part edges are spaced apart from each other in a second direction that is perpendicular to the first direction. Each of the two second support-part edges is physically connected to the two first support-part edges. The source wire, the gate wire and the drain wire cross at least one of the two second support-part edges in plan view.

A semiconductor device including an active layer made of III-V group semiconductors, a source electrode and a drain electrode disposed on the active layer, a gate electrode disposed on or above the active layer and between the source electrode and the drain electrode, an interlayer dielectric covering the source electrode, the drain electrode, and the gate electrode and having a plurality of inter-gate via holes. The semiconductor device further includes an inter-source layer, an inter-drain layer, and an inter-gate layer disposed on the interlayer dielectric. The semiconductor device further includes an inter-gate plug filled in the inter-gate via hole and electrically connected to the gate electrode and the inter-gate layer, and a gate field plate being separated from the gate electrode and electrically connected to the gate electrode through the inter-gate layer.

A semiconductor device according to an embodiment includes: a first nitride semiconductor layer having a first surface and a second surface; a first source electrode provided on the first surface; a first drain electrode provided on the first surface; a first gate electrode provided on the first surface between the first source electrode and the first drain electrode; a second nitride semiconductor layer having a third surface and a fourth surface, the third surface being provided on the second surface and facing the second surface, and the second nitride semiconductor layer having a smaller band gap than the first nitride semiconductor layer; and a first semiconductor device having a fifth surface provided on the fourth surface and facing the fourth surface with a size equal to or smaller than a size of the fourth surface, the first semiconductor device including a first semiconductor material having a smaller band gap than the second nitride semiconductor layer.

A semiconductor device includes an active layer having first and second active regions, first and second source electrodes, first and second drain electrodes, first and second gate electrodes, a first source metal layer, first and second drain metal layers, and a source pad electrically connected to the first source metal layer. The second drain metal layer is electrically connected to the second drain electrode and the first source metal layer. A projection of the second drain metal layer on the active layer forms a drain metal layer region. An projection of the source pad on the active layer forms a source pad region. An area of an overlapping region between the source pad region and the drain metal layer region is smaller than or equal to 40% of an area of the drain metal layer region.

A III-N enhancement-mode transistor includes a III-N structure including a conductive channel, source and drain contacts, and a gate electrode between the source and drain contacts. An insulator layer is over the III-N structure, with a recess formed through the insulator layer in a gate region of the transistor, with the gate electrode at least partially in the recess. The transistor further includes a field plate having a portion between the gate electrode and the drain contact, the field plate being electrically connected to the source contact. The gate electrode includes an extending portion that is outside the recess and extends towards the drain contact. The separation between the conductive channel and the extending portion of the gate electrode is greater than the separation between the conductive channel and the portion of the field plate that is between the gate electrode and the drain contact.

In order to produce a power semiconductor module, a circuit carrier is populated with a semiconductor chip and with an electrically conductive contact element. After populating, the semiconductor chip and the contact element are embedded into a dielectric embedding compound, and the contact element is exposed. In addition, an electrically conductive base layer is produced which electrically contacts the exposed contact element and which bears on the embedding compound and the exposed contact element. A prefabricated metal film is applied to the base layer by means of an electrically conductive connection layer.

A method for fabricating semiconductor device includes: forming a first semiconductor layer and an insulating layer on a substrate; removing the insulating layer and the first semiconductor layer to form openings; forming a second semiconductor layer in the openings; and patterning the second semiconductor layer, the insulating layer, and the first semiconductor layer to form fin-shaped structures.