Abstract: In an embodiment, a Group III nitride-based transistor device includes a source electrode, a drain electrode and a gate electrode positioned on a first major surface of a Group III nitride based-based layer, wherein the gate electrode is laterally arranged between the source electrode and the drain electrode, a passivation layer arranged on the first major surface and a field plate coupled to the source electrode, the field plate having a lower surface arranged on the passivation layer. The field plate is laterally arranged between and laterally spaced apart from the gate electrode and the drain electrode.

Abstract: A method of fabricating a semiconductor device includes: epitaxially growing a multilayer Group-III nitride structure on a first surface of a substrate; removing portions of the multilayer structure to form a mesa arranged on the first surface; applying insulating material to the first surface of the substrate so that side faces of the mesa are embedded in the insulating material; forming an electrode on a top surface of the mesa; forming a via in the insulating material that extends from the top surface of the insulating material to the first surface of the substrate; inserting conductive material into the via to form a conductive via; applying an electrically conductive redistribution structure to the upper surface and electrically connecting the conductive via to the electrode; and successively removing portions of a second surface of the substrate, to expose the insulating material and form a worked second surface including the insulating material.

Abstract: In an embodiment, a Group III nitride-based semiconductor device includes: a multilayer Group III nitride-based structure including a first major surface; and a source electrode, a gate electrode and a drain electrode arranged on the first major surface. The gate electrode is laterally arranged between the source electrode and the drain electrode and a metallization structure arranged on the first major surface. The metallization structure includes an electrically insulating layer arranged on the source electrode, the gate electrode and the drain electrode and a conductive redistribution structure electrically connected to the source electrode, the gate electrode and the drain electrode. One or more cavities are located in the electrically insulating layer of the metallization structure.

Abstract: A semiconductor device includes a support substrate having a first surface capable of supporting the epitaxial growth of at least one III-V semiconductor and a second surface opposing the first surface, at least one mesa positioned on the first surface, each mesa including an epitaxial III-V semiconductor-based multi-layer structure on the first surface of the support substrate, the III-V semiconductor-based multi-layer structure forming a boundary with the first surface and a parasitic channel suppression region positioned laterally adjacent the boundary.

Abstract: A semiconductor device includes a composite layer having a first and second opposing surfaces. The composite layer includes a mesa and a first insulating layer. The mesa has top and bottom surfaces and side faces. The side faces are embedded in the first insulating layer. The mesa includes a Group III nitride-based multilayer structure providing a Group III nitride based device having first and second electrodes arranged on the mesa top surface. First and second outer contacts are positioned on the second surface of the composite layer. A first conductive via extends through the first insulating layer and is electrically coupled to the first electrode on the mesa top surface and to the first outer contact. A second conductive via extends through the first insulating layer and is electrically coupled to the second electrode on the mesa top surface and to the second outer contact.

Abstract: A Group III nitride-based transistor device is provided that has a gate drain capacitance (CGD), a drain source capacitance (CDS) and a drain source on resistance (RDSon). A ratio of the gate drain capacitance (CGD) at a drain source voltage (VDS) of 0V, CGD (0V), and the gate drain capacitance CGD at a value of VDS>0V, CGDV, is at least 3:1, wherein VDS is less than 15V.

Abstract: A method includes providing a semiconductor body, forming a thermosensitive element on or within the semiconductor body, forming a structured laser-reflective mask on the upper surface of the semiconductor body that covers the thermosensitive element and includes first and second openings, and performing a laser thermal annealing process that transmits laser energy through the first and second openings and into the semiconductor body, wherein the thermosensitive element comprises a critical temperature at which the thermosensitive element is irreparably damaged, wherein the laser thermal annealing process brings portions of the semiconductor body that are underneath the first and second openings to above the critical temperature, and wherein during the laser thermal annealing process the thermosensitive element remains below the critical temperature.

Abstract: A semiconductor body having a base carrier portion and a type III-nitride semiconductor portion is provided. The type III-nitride semiconductor portion includes a heterojunction and two-dimensional charge carrier gas. One or more ohmic contacts are formed in the type III-nitride semiconductor portion, the ohmic contacts forming an ohmic connection with the two-dimensional charge carrier gas. A gate structure is configured to control a conductive state of the two-dimensional charge carrier gas. Forming the one or more ohmic contacts comprises forming a structured laser-reflective mask on the upper surface of the type III-nitride semiconductor portion, implanting dopant atoms into the upper surface of the type III-nitride semiconductor portion, and performing a laser thermal anneal that activates the implanted dopant atoms.

Abstract: A semiconductor package includes a mounting platform including an electrically insulating substrate and structured metallization layers, a semiconductor die mounted on an upper surface of the mounting platform, the semiconductor die including a first terminal and a second terminal, the first terminal disposed on a second surface of the semiconductor die that faces the mounting platform, the second terminal disposed on a first surface of the semiconductor die that faces away from the mounting platform, and a heat sink integrally formed in the mounting platform. The heat sink is directly underneath the semiconductor die and is thermally coupled to the semiconductor die. The heat sink extends from the upper surface of the mounting platform to a lower surface of the mounting platform. The heat sink includes one or more discrete metal blocks disposed within an opening formed in the electrically insulating substrate.

Abstract: A semiconductor device includes a support substrate having a first surface capable of supporting the epitaxial growth of at least one III-V semiconductor and a second surface opposing the first surface, at least one mesa positioned on the first surface, each mesa including an epitaxial III-V semiconductor-based multi-layer structure on the first surface of the support substrate, the III-V semiconductor-based multi-layer structure forming a boundary with the first surface and a parasitic channel suppression region positioned laterally adjacent the boundary.

Abstract: A semiconductor device includes a support substrate having a first surface capable of supporting the epitaxial growth of at least one III-V semiconductor and a second surface opposing the first surface, at least one mesa positioned on the first surface, each mesa including an epitaxial III-V semiconductor-based multi-layer structure on the first surface of the support substrate, the III-V semiconductor-based multi-layer structure forming a boundary with the first surface and a parasitic channel suppression region positioned laterally adjacent the boundary.

Abstract: A device is provided including a power transistor at an output node, which is coupled to a load terminal of the power transistor. A DC feed path is also provided. One or more discrete capacitors are coupled between the DC feed path and a reference potential. A first capacitor of the one or more discrete capacitors which is closest to the output node is a trench capacitor device.

Abstract: A semiconductor body having a base carrier portion and a type III-nitride semiconductor portion is provided. The type III-nitride semiconductor portion includes a heterojunction and two-dimensional charge carrier gas. One or more ohmic contacts are formed in the type III-nitride semiconductor portion, the ohmic contacts forming an ohmic connection with the two-dimensional charge carrier gas. A gate structure is configured to control a conductive state of the two-dimensional charge carrier gas. Forming the one or more ohmic contacts comprises forming a structured laser-reflective mask on the upper surface of the type III-nitride semiconductor portion, implanting dopant atoms into the upper surface of the type III-nitride semiconductor portion, and performing a laser thermal anneal that activates the implanted dopant atoms.

Abstract: In an embodiment, a Group III nitride-based transistor device includes a first passivation layer arranged on a first major surface of a Group III nitride-based layer, a second passivation layer arranged on the first passivation layer, a source ohmic contact, a drain ohmic contact and a gate positioned on the first major surface of a Group III nitride-based layer, and a field plate, the field plate being laterally arranged between and spaced apart from the gate and the drain ohmic contact.

Abstract: In an embodiment, a Group III nitride-based transistor device includes a source electrode, a drain electrode and a gate electrode positioned on a first major surface of a Group III nitride based-based layer, wherein the gate electrode is laterally arranged between the source electrode and the drain electrode, a passivation layer arranged on the first major surface and a field plate coupled to the source electrode, the field plate having a lower surface arranged on the passivation layer. The field plate is laterally arranged between and laterally spaced apart from the gate electrode and the drain electrode.

Abstract: In an embodiment, a method for fabricating a semiconductor wafer includes: epitaxially growing a III-V semiconductor on a first surface of a foreign wafer having a thickness tw, the first surface being capable of supporting the epitaxial growth of at least one III-V semiconductor layer, the wafer having a second surface opposing the first surface; removing portions of the III-V semiconductor to produce a plurality of mesas including the III-V semiconductor arranged on the first surface of the wafer; applying an insulation layer to regions of the wafer arranged between the mesas; and progressively removing portions of the second surface of the wafer, exposing the insulation layer in regions adjacent the mesas and producing a worked second surface.

Abstract: In accordance with an embodiment of the present invention, a semiconductor chip includes a device region disposed in or over a substrate, a doped region disposed in the device region, and a through via disposed in the substrate. The through via extends through the doped region.

Abstract: A semiconductor device includes a composite layer having a first and second opposing surfaces. The composite layer includes a mesa and a first insulating layer. The mesa has top and bottom surfaces and side faces. The side faces are embedded in the first insulating layer. The mesa includes a Group III nitride-based multilayer structure providing a Group III nitride based device having first and second electrodes arranged on the mesa top surface. First and second outer contacts are positioned on the second surface of the composite layer. A first conductive via extends through the first insulating layer and is electrically coupled to the first electrode on the mesa top surface and to the first outer contact. A second conductive via extends through the first insulating layer and is electrically coupled to the second electrode on the mesa top surface and to the second outer contact.

Abstract: In an embodiment, a semiconductor device includes a support layer having a first surface configured to support epitaxial growth of at least one Group III nitride, an epitaxial Group III nitride-based multi-layer structure positioned on the first surface of the support layer, and a parasitic channel suppression region positioned at the first surface of the support layer.

Abstract: A packaged amplifier circuit includes an RF package with a die pad, and RF input and output leads extending away from the die pad opposite directions. An RF transistor die is mounted on the die pad such that a first outer edge side of the RF transistor die faces the first RF lead and a second outer edge side of the RF transistor die faces the second RF lead. A passive electrical connector is integrally formed in the RF transistor die. The passive electrical connector includes a first end connection point closer to the first outer edge side, and a second end connection point closer to the second outer edge side. A first discrete reactive device is mounted on the die pad between the first outer edge side and the first RF lead. The passive electrical connector electrically couples the first discrete reactive device to the second RF lead.