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 passive circuit component includes an edge having a low line edge roughness (LER). A method for manufacturing the passive circuit component includes a self-aligned double patterning (SADP) etch process using a tri-layer process flow. The tri-layer process flow includes use of an underlayer, hard mask, and photoresist. The passive circuit component made by this method achieves improved mismatch between like components due to the low LER.

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: 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: 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: 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: One example provides an enhancement-mode High Electron Mobility Transistor (HEMT) includes a substrate, a Group IIIA-N active layer over the substrate, a Group IIIA-N barrier layer over the active layer, and at least one isolation region through the barrier layer to provide an isolated active area having the barrier layer on the active layer. A gate stack is located between source and drain contacts to the active layer. A tunnel diode in the gate stack includes an n-GaN layer on an InGaN layer on a p-GaN layer located on the barrier layer.

Abstract: One example provides an enhancement-mode High Electron Mobility Transistor (HEMT) includes a substrate, a Group IIIA-N active layer over the substrate, a Group IIIA-N barrier layer over the active layer, and at least one isolation region through the barrier layer to provide an isolated active area having the barrier layer on the active layer. A gate stack is located between source and drain contacts to the active layer. A tunnel diode in the gate stack includes an n-GaN layer on an InGaN layer on a p-GaN layer located on the barrier layer.

Abstract: An enhancement-mode High Electron Mobility Transistor (HEMT) includes a substrate, a Group IIIA-N active layer on the substrate, a Group IIIA-N barrier layer on the active layer, and at least one isolation region through the barrier layer to provide an isolated active area having the barrier layer on the active layer. A p-GaN layer is on the barrier layer. A tunnel diode in the gate stack includes an n-GaN layer on an InGaN layer on the p-GaN layer. A gate electrode is over the n-GaN layer. A drain having a drain contact is on the barrier layer to provide contact to the active layer, and a source having a source contact is on the barrier layer provides contact to the active layer. The tunnel diode provides a gate contact to eliminate the need to form a gate contact directly to the p-GaN layer.

Abstract: An enhancement-mode High Electron Mobility Transistor (HEMT) includes a substrate, a Group IIIA-N active layer on the substrate, a Group IIIA-N barrier layer on the active layer, and at least one isolation region through the barrier layer to provide an isolated active area having the barrier layer on the active layer. A p-GaN layer is on the barrier layer. A tunnel diode in the gate stack includes an n-GaN layer on an InGaN layer on the p-GaN layer. A gate electrode is over the n-GaN layer. A drain having a drain contact is on the barrier layer to provide contact to the active layer, and a source having a source contact is on the barrier layer provides contact to the active layer. The tunnel diode provides a gate contact to eliminate the need to form a gate contact directly to the p-GaN layer.

Abstract: An integrated circuit includes a Schottky diode having a cathode defined by an n-type semiconductor region, an anode defined by a cobalt silicide region, and a p-type region laterally annularly encircling the cobalt silicide region. The resulting p-n junction forms a depletion region under the Schottky junction that reduces leakage current through the Schottky diodes in reverse bias operation. An n+-type contact region is laterally separated by the p-type region from the first silicide region and a second cobalt silicide region is formed in the n-type contact region. The silicided regions are defined by openings in a silicon blocking dielectric layer. Dielectric material is left over the p-type region. The p-type region may be formed simultaneously with source/drain regions of a PMOS transistor.

Abstract: An integrated circuit includes a Schottky diode having a cathode defined by an n-type semiconductor region, an anode defined by a cobalt silicide region, and a p-type region laterally annularly encircling the cobalt silicide region. The resulting p-n junction forms a depletion region under the Schottky junction that reduces leakage current through the Schottky diodes in reverse bias operation. An n+-type contact region is laterally separated by the p-type region from the first silicide region and a second cobalt silicide region is formed in the n-type contact region. The silicided regions are defined by openings in a silicon blocking dielectric layer. Dielectric material is left over the p-type region. The p-type region may be formed simultaneously with source/drain regions of a PMOS transistor.

Abstract: A method of fabricating an integrated circuit (IC) including at least one drain extended MOS (DEMOS) transistor and ICs therefrom includes providing a substrate having a semiconductor surface, the semiconductor surface including at least a first surface region that provides a first dopant type. A patterned masking layer is formed on the first surface region, wherein at least one aperture in the masking layer is defined. The first surface region is etched to form at least one trench region corresponding to a position of the aperture. A dopant of a first dopant type is implanted to raise a concentration of the first dopant type in a first dopant type drift region located below the trench region. After the implanting, the trench region is filled with a dielectric fill material. A body region is then formed having a second dopant type in a portion of the first surface region. A gate dielectric is then formed over a surface of the body region and the first surface region.

Abstract: A method of fabricating an integrated circuit (IC) including at least one drain extended MOS (DEMOS) transistor and ICs therefrom includes providing a substrate having a semiconductor surface, the semiconductor surface including at least a first surface region that provides a first dopant type. A patterned masking layer is formed on the first surface region, wherein at least one aperture in the masking layer is defined. The first surface region is etched to form at least one trench region corresponding to a position of the aperture. A dopant of a first dopant type is implanted to raise a concentration of the first dopant type in a first dopant type drift region located below the trench region. After the implanting, the trench region is filled with a dielectric fill material. A body region is then formed having a second dopant type in a portion of the first surface region. A gate dielectric is then formed over a surface of the body region and the first surface region.

Abstract: Cobalt silicide (CoSi2) Schottky diodes fabricated per the current art suffer from excess leakage currents in reverse bias. In this invention, an floating p-type region encircles each anode of a CoSi2 Schottky diode comprising of one or more CoSi2 anodes. The resulting p-n junction forms a depletion region under the Schottky junction that reduces leakage current through the Schottky diodes in reverse bias operation.