Abstract: Disclosed is a semiconductor device comprising a group 13 nitride heterojunction comprising a first layer having a first bandgap and a second layer having a second bandgap, wherein the first layer is located between a substrate and the second layer; and a Schottky electrode and a first further electrode each conductively coupled to a different area of the heterojunction, said Schottky electrode comprising a central region and an edge region, wherein the element comprises a conductive barrier portion located underneath said edge region only of the Schottky electrode for locally increasing the Schottky barrier of the Schottky electrode. A method of manufacturing such a semiconductor device is also disclosed.

Abstract: A method of manufacturing a semiconductor device includes forming trench isolation structures, exposing some of the trench isolation structures 28 to leave others 30 masked, and then selectively etching a buried layer to form a cavity 32 under an active device region 34. The active device region 34 is supported by support regions in the exposed trenches 28. The buried layer may be a SiGe layer on a Si substrate.

Abstract: Disclosed is a semiconductor device comprising a group 13 nitride heterojunction comprising a first layer having a first bandgap and a second layer having a second bandgap, wherein the first layer is located between a substrate and the second layer; and a Schottky electrode and a first further electrode each conductively coupled to a different area of the heterojunction, said Schottky electrode comprising a central region and an edge region, wherein the element comprises a conductive barrier portion located underneath said edge region only of the Schottky electrode for locally increasing the Schottky barrier of the Schottky electrode. A method of manufacturing such a semiconductor device is also disclosed.

Abstract: A method of manufacturing a semiconductor device includes forming trench isolation structures, exposing some of the trench isolation structures 28 to leave others 30 masked, and then selectively etching a buried layer to form a cavity 32 under an active device region 34. The active device region 34 is supported by support regions in the exposed trenches 28. The buried layer may be a SiGe layer on a Si substrate.

Abstract: In an example embodiment, a heterojunction device comprises a substrate, a multilayer structure disposed on the substrate. The multilayer structure has a first layer having a first semiconductor disposed on top of the substrate; a second layer has a second semiconductor is disposed on top of the first layer defining an interface between them. The second semiconductor differs from the first semiconductor such that a 2D Electron Gas forms adjacent to the interface. A first terminal couples to a first area of the interface between the first and second layers and a second terminal couples to a second area of the interface between the first and second layers; an electrically conducting channel comprises a metal or a region of the first layer with a higher defect density than another region of the first layer. The channel connects the second terminal and a region of the first layer such that electric charge can flow between them.

Abstract: A semiconductor device comprising at least one active layer on a substrate and a first contact to the at least one active layer, the first contact comprising a metal in contact with the at least one active layer and a capping layer on the metal, the capping layer comprising a diffusion barrier, wherein the capping layer is patterned to form a pattern comprising regions of the contact covered by the capping layer and regions of the contact that are uncovered.

Abstract: An isolated semiconductor circuit comprising: a first sub-circuit and a second sub-circuit; a backend that includes an electrically isolating connector between the first and second sub-circuits; a lateral isolating trench between the semiconductor portions of the first and second sub-circuits, wherein the lateral isolating trench extends along the width of the semiconductor portions of the first and second sub-circuits, wherein one end of the isolating trench is adjacent the backend, and wherein the isolating trench is filled with an electrically isolating material.

Abstract: A cascode circuit arrangement has a low voltage MOSFET and a depletion mode power device mounted on a substrate (for example a ceramic substrate), which can then be placed in a semiconductor package. This enables inductances to be reduced, and can enable a three terminal packages to be used if desired.

Abstract: Embodiments relate to a diode circuit which uses a Schottky diode. A parallel bypass branch has a switch and bypass diode in series. The operation of the switch is dependent on the voltage across the Schottky diode so that the bypass function is only effective when a desired voltage is reached. The diode circuit can be used as a replacement for a single diode, and provides bypass current protection preferably without requiring any external control input.

Abstract: Disclosed is a semiconductor device comprising a group 13 nitride heterojunction comprising a first layer having a first bandgap and a second layer having a second bandgap, wherein the first layer is located between a substrate and the second layer; and a Schottky electrode and a first further electrode each conductively coupled to a different area of the heterojunction, said Schottky electrode comprising a central region and an edge region, wherein the element comprises a conductive barrier portion located underneath said edge region only of the Schottky electrode for locally increasing the Schottky barrier of the Schottky electrode. A method of manufacturing such a semiconductor device is also disclosed.

Abstract: Consistent with an example embodiment, a GaN heterojunction structure has a three-layer dielectric structure. The lowermost and middle portions of the gate electrode together define the gate foot, and this is associated with two dielectric layers. A thinner first dielectric layer is adjacent the gate edge at the bottom of the gate electrode. The second dielectriclayer corresponds to the layer in the conventional structure, and it is level with the main portion of the gate foot.

Abstract: An isolated semiconductor circuit comprising: a first sub-circuit and a second sub-circuit; a backend that includes an electrically isolating connector between the first and second sub-circuits; a lateral isolating trench between the semiconductor portions of the first and second sub-circuits, wherein the lateral isolating trench extends along the width of the semiconductor portions of the first and second sub-circuits, wherein one end of the isolating trench is adjacent the backend, and wherein the isolating trench is filled with an electrically isolating material.

Abstract: An isolated semiconductor circuit comprising: a first sub-circuit and a second sub-circuit; a backend that includes an electrically isolating connector between the first and second sub-circuits; a lateral isolating trench between the semiconductor portions of the first and second sub-circuits, wherein the lateral isolating trench extends along the width of the semiconductor portions of the first and second sub-circuits, wherein one end of the isolating trench is adjacent the backend, and wherein the isolating trench is filled with an electrically isolating material.

Abstract: A cascode circuit arrangement has a low voltage MOSFET and a depletion mode power device mounted on a substrate (for example a ceramic substrate), which can then be placed in a semiconductor package. This enables inductances to be reduced, and can enable a three terminal packages to be used if desired.

Abstract: A GaN hetereojunction structure has a three-layer dielectric structure. The lowermost and middle portions of the gate electrode together define the gate foot, and this is associated with two dielectric layers. A thinner first dielectric layer is adjacent the gate edge at the bottom of the gate electrode. The second dielectric layer corresponds to the layer in the conventional structure, and it is level with the main portion of the gate foot.

Abstract: An isolated semiconductor circuit comprising: a first sub-circuit and a second sub-circuit; a backend that includes an electrically isolating connector between the first and second sub-circuits; a lateral isolating trench between the semiconductor portions of the first and second sub-circuits, wherein the lateral isolating trench extends along the width of the semiconductor portions of the first and second sub-circuits, wherein one end of the isolating trench is adjacent the backend, and wherein the isolating trench is filled with an electrically isolating material.

Abstract: A cascoded power semiconductor circuit has a clamp circuit between the source and gate of a gallium nitride or silicon carbide FET to provide avalanche protection for the cascode MOSFET transistor.

Abstract: Disclosed is a semiconductor device comprising a group 13 nitride heterojunction comprising a first layer having a first bandgap and a second layer having a second bandgap, wherein the first layer is located between a substrate and the second layer; and a Schottky electrode and a first further electrode each conductively coupled to a different area of the heterojunction, said Schottky electrode comprising a central region and an edge region, wherein the element comprises a conductive barrier portion located underneath said edge region only of the Schottky electrode for locally increasing the Schottky barrier of the Schottky electrode. A method of manufacturing such a semiconductor device is also disclosed.

Abstract: The present invention relates to a method for fabricating a FinFET on a substrate. The method comprises providing a substrate with an active semiconductor layer on an insulator layer, and concurrently fabricating trench isolation regions in the active semiconductor layer for electrically isolating different active regions in the active semiconductor layer from each other, and trench gate-isolation regions in the active semiconductor layer for electrically isolating at least one gate region of the FinFET in the active semiconductor layer from a fin-shaped channel region of the FinFET in the active semiconductor layer.

Abstract: The present invention relates to a FinFET with separate gates and to a method for fabricating the same. A dielectric gate-separation layer between first and second gate electrodes has an extension in a direction pointing from a first to a second gate layer that is smaller than a lateral extension of the fin between its opposite lateral faces. This structure corresponds with a processing method that starts from a covered basic FinFET structure with a continuous first gate layer, and proceeds to remove parts of the first gate layer and of a first gate-isolation layer through a contact opening to the gate layer. Subsequently, a replacement gate-isolation layer that at the same time forms the gate separation layer fabricated, followed by filling the tunnel with a replacement gate layer and a metal filling.