Abstract: A semiconductor device includes a gallium nitride based low threshold depletion mode transistor (GaN FET) with a threshold potential between ?10 volts and ?0.5 volts. The GaN FET has a channel layer of III-N semiconductor material including gallium and nitrogen that supports a two-dimensional electron gas (2DEG). The GaN FET has a barrier layer of III-N semiconductor material including aluminum and nitrogen over the channel layer. The GaN FET further has a p-type gate of III-N semiconductor material including gallium and nitrogen. A bottom surface of the gate, adjacent to the barrier layer, does not extend past a top surface of the barrier layer, located opposite from the channel layer. The GaN FET is free of a dielectric layer between the gate and the barrier layer.

Abstract: An electronic device includes an one of aluminum gallium nitride, aluminum nitride, indium aluminum nitride, or indium aluminum gallium nitride back barrier layer over a buffer structure, a gallium nitride layer over the back barrier layer, a hetero-epitaxy structure over the gallium nitride layer, first and second transistors over the hetero-epitaxy structure, and a hole injector having a doped gallium nitride structure over the hetero-epitaxy structure and a conductive structure partially over the doped gallium nitride structure to inject holes to form a hole layer proximate an interface of the back barrier layer and the buffer structure to mitigate vertical electric field back gating effects for the first transistor.

Abstract: GaN devices with a modified heterojunction structure and methods of making thereof are described. The GaN device comprises a heterojunction structure modified to include one or more deactivated regions. The heterojunction structure of the deactivated regions has different structural configurations than that of the as-grown heterojunction structure. The locally confined structural alteration of the heterojunction structure weakens or prohibits 2DEG formation in the deactivated regions. Moreover, the amount of net charges mapped to a field plate positioned above the heterojunction structure can be locally reduced or eliminated. Consequently, the electric field present between the heterojunction structure and the field plate can be reduced.

Abstract: An electronic device includes an one of aluminum gallium nitride, aluminum nitride, indium aluminum nitride, or indium aluminum gallium nitride back barrier layer over a buffer structure, a gallium nitride layer over the back barrier layer, a hetero-epitaxy structure over the gallium nitride layer, first and second transistors over the hetero-epitaxy structure, and a hole injector having a doped gallium nitride structure over the hetero-epitaxy structure and a conductive structure partially over the doped gallium nitride structure to inject holes to form a hole layer proximate an interface of the back barrier layer and the buffer structure to mitigate vertical electric field back gating effects for the first transistor.

Abstract: In some examples, a transistor comprises a gallium nitride (GaN) layer; a GaN-based alloy layer having a top side and disposed on the GaN layer, wherein source, drain, and gate contact structures are supported by the GaN layer; and a first doped region positioned in a drain access region and extending from the top side into the GaN layer.

Abstract: In some examples, a transistor comprises a gallium nitride (GaN) layer; a GaN-based alloy layer having a top side and disposed on the GaN layer, wherein source, drain, and gate contact structures are supported by the GaN layer; and a first doped region positioned in a drain access region and extending from the top side into the GaN layer.

Abstract: An electronic device includes an one of aluminum gallium nitride, aluminum nitride, indium aluminum nitride, or indium aluminum gallium nitride back barrier layer over a buffer structure, a gallium nitride layer over the back barrier layer, a hetero-epitaxy structure over the gallium nitride layer, first and second transistors over the hetero-epitaxy structure, and a hole injector having a doped gallium nitride structure over the hetero-epitaxy structure and a conductive structure partially over the doped gallium nitride structure to inject holes to form a hole layer proximate an interface of the back barrier layer and the buffer structure to mitigate vertical electric field back gating effects for the first transistor.

Abstract: A gallium nitride (“GaN”)-based semiconductor device, and method of forming the same. In one example, the semiconductor device includes a channel layer including GaN, and a barrier layer of a first III-N material over the channel layer. The semiconductor device also includes a cap layer of a second III-N material including indium over the barrier layer, wherein the cap layer may have the effect of modifying a threshold voltage and gate leakage current of the semiconductor device.

Abstract: One example described herein includes an integrated circuit (IC) that includes a gallium-nitride (GaN) transistor device. The IC includes GaN active layers that define an active region, and a gate structure arranged on a surface of the active region. The IC also includes a source arranged on a first side of the gate structure and a drain arranged on a second side of the gate structure. The IC further includes at least one source field-plate structure conductively coupled to the source and a gate-level field-plate structure that is coupled to the source.

Abstract: A method of fabricating a semiconductor device includes providing a GaN substrate with an epitaxial layer formed thereover, the epitaxial layer forming a heterojunction with the GaN substrate, the heterojunction supporting a 2-dimensional electron gas (2DEG) channel in the GaN substrate. A composite surface passivation layer is formed over a top surface of the epitaxial layer, wherein the composite surface passivation layer comprises a first passivation layer portion formed proximate to a first region of the GaN device and a second passivation layer portion formed proximate to a second region of the GaN device. The first and second passivation layer portions are disposed laterally adjacent to each other over the epitaxial layer, wherein the first passivation layer portion is formed in a first process and the second passivation layer portion is formed in a second process.

Abstract: An integrated circuit, including a source region, a drain region, a channel region between the source region and the drain region, and a gate for inducing a conductive path through the channel region. The integrated circuit also includes structure, proximate a curved length of the gate, for inhibiting current flow along a portion of the channel region.

Abstract: A microelectronic device includes a GaN FET on a substrate such as silicon and a buffer layer of III-N semiconductor material. The GaN FET includes both source contacts and drain contacts to a channel layer of III-N semiconductor material. Source contacts to the source region are placed farther from the gate electrode fingertip than drain contacts to the drain region.

Abstract: The present invention provides a capacitor having a first structure made of a metal layer and a second structure made of the same metal layer and a dielectric layer between the first and the second metal structure, wherein the dielectric layer has a relative permittivity greater than 4, in particular greater than 6. It also provides a monolithically integrated circuit including such a capacitor and optionally other components. A method of manufacturing such a capacitor is also provided.

Abstract: A semiconductor device includes a gallium nitride based low threshold depletion mode transistor (GaN FET) with a threshold potential between ?10 volts and ?0.5 volts. The GaN FET has a channel layer of III-N semiconductor material including gallium and nitrogen that supports a two-dimensional electron gas (2 DEG). The GaN FET has a barrier layer of III-N semiconductor material including aluminum and nitrogen over the channel layer. The GaN FET further has a p-type gate of III-N semiconductor material including gallium and nitrogen. A bottom surface of the gate, adjacent to the barrier layer, does not extend past a top surface of the barrier layer, located opposite from the channel layer. The GaN FET is free of a dielectric layer between the gate and the barrier layer.

Abstract: Fabrication methods, electronic devices and enhancement mode gallium nitride transistors include a gallium nitride interlayer between a hetero-epitaxy structure and a p-doped gallium nitride layer and/or between the p-doped gallium nitride layer and a gate structure to mitigate p-type dopant diffusion, improve current collapse performance, and mitigate positive-bias temperature instability. In certain examples, the interlayer or interlayers is/are fabricated using epitaxial deposition with no p-type dopant source. In certain fabrication process examples, epitaxial deposition or growth is interrupted after the depositing an aluminum gallium nitride layer of the hetero-epitaxy structure, after which growth is resumed to deposit the first gallium nitride interlayer over the aluminum gallium nitride layer to mitigate p-type dopant diffusion and current collapse.

Abstract: A High Electron Mobility Transistor (HEMT) includes an active layer on a substrate, and a Group IIIA-N barrier layer on the active layer. An isolation region is through the barrier layer to provide at least one isolated active area including the barrier layer on the active layer. A gate is over the barrier layer. A drain includes at least one drain finger including a fingertip having a drain contact extending into the barrier layer to contact to the active layer and a source having a source contact extending into the barrier layer to contact to the active layer. The source forms a loop that encircles the drain. The isolation region includes a portion positioned between the source and drain contact so that there is a conduction barrier in a length direction between the drain contact of the fingertip and the source.

Abstract: In some examples, a gallium nitride (GaN)-based transistor, comprises a substrate; a GaN layer supported by the substrate; an aluminum nitride gallium (AlGaN) layer supported by the GaN layer; a p-doped GaN structure supported by the AlGaN layer; and multiple p-doped GaN blocks supported by the AlGaN layer, each of the multiple p-doped GaN blocks physically separated from the remaining multiple p-doped GaN blocks, wherein first and second contours of a two-dimensional electron gas (2DEG) of the GaN-based transistor are at an interface of the AlGaN and GaN layers.

Abstract: A semiconductor device a strapped interconnect line, which in turn includes a first interconnect line at a first level above a semiconductor substrate, and a second interconnect line at a second level above the interconnect substrate. A dielectric capping layer is located directly on the first interconnect line. A plurality of strapping vias are connected between the first interconnect line and the second interconnect line. Each of the strapping vias extends from a first side of the first interconnect line to a second side of the second interconnect line.

Abstract: A method includes applying a DC stress condition to a transistor for a predetermined stress time, measuring an impedance of the transistor after the predetermined stress time, and repeating the application of the DC stress condition and the measurement of the impedance until the measured impedance exceeds an impedance threshold or a total stress time exceeds a time threshold, where the DC stress condition includes applying a non-zero drain voltage signal to a drain terminal of the transistor, applying a gate voltage signal to a gate terminal of the transistor, and applying a non-zero source current signal to a source terminal of the transistor.

Abstract: In some examples, a gallium nitride (GaN)-based transistor, comprises a substrate; a GaN layer supported by the substrate; an aluminum nitride gallium (AlGaN) layer supported by the GaN layer; a p-doped GaN structure supported by the AlGaN layer; and multiple p-doped GaN blocks supported by the AlGaN layer, each of the multiple p-doped GaN blocks physically separated from the remaining multiple p-doped GaN blocks, wherein first and second contours of a two-dimensional electron gas (2DEG) of the GaN-based transistor are at an interface of the AlGaN and GaN layers.