Fabricating a regrown GaN p-n junction includes depositing a n-GaN layer on a substrate including n.sup.+-GaN, etching a surface of the n-GaN layer to yield an etched surface, depositing a p-GaN layer on the etched surface, etching a portion of the n-GaN layer and a portion of the p-GaN layer to yield a mesa opposite the substrate, and passivating a portion of the p-GaN layer around an edge of the mesa. The regrown GaN p-n junction is defined at an interface between the n-GaN layer and the p-GaN layer. The regrown GaN p-n junction includes a substrate, a n-GaN layer on the substrate having an etched surface, a p-GaN layer on the etched surface, a mesa defined by an etched portion of the n-GaN layer and an etched portion of the p-GaN layer, and a passivated portion of the p-GaN layer around an edge of the mesa.

The semiconductor device includes a mesa diode structure(20) and a protective layer(17b). The mesa diode structure includes, from bottom to top, a P-type semiconductor layer(11), a first N-type semiconductor layer(12), and a second N-type semiconductor layer(13) having a higher impurity concentration than the first N-type semiconductor layer. The protective layer is arranged on a side wall around the mesa diode structure seen in a plane. Specifically, the protective layer is arranged on an upper side surface(11c) of the P-type semiconductor layer and on side surfaces(12a,13a) of the first N-type semiconductor layer and the second N-type semiconductor layer, but is not arranged on a lower side surface of the P-type semiconductor layer. A bevel angle(30) of a PN junction plane between the P-type semiconductor layer and the first N-type semiconductor layer to the upper side surface of the P-type semiconductor layer is set to 85 to 120 degrees.

The present application belongs to the technical field of semiconductor power devices and provides a semiconductor power device. The semiconductor power device includes an n-shaped substrate, an n-shaped epitaxial layer positioned on the n-shaped substrate, and at least three grooves recessed inside the n-shaped epitaxial layer, where a portion of the n-shaped epitaxial layer between two adjacent grooves of the at least three grooves is a mesa structure, an upper part of the mesa structure is provided with a p-shaped body region, and an n-shaped source region is provided inside the p-shaped body region. The mesa structure includes at least one mesa structure with a lower width being a first width and at least one mesa structure with a lower width being a second width, and the second width is greater than the first width.

Semiconductor devices having recessed edges with plated structures, semiconductor assemblies formed therefrom, and associated systems and methods are disclosed herein. In one embodiment, a semiconductor assembly includes a first semiconductor device and a second semiconductor device. The first semiconductor device can include an upper surface and a first dielectric layer over the upper surface, the second semiconductor device can include a lower surface and a second dielectric layer over the lower surface, and the first and second dielectric layers can be bonded to couple the first and second semiconductor devices. The first and second dielectric layers can each include a plurality of inwardly extending recesses exposing a plurality of metal structures on the respective upper and lower surfaces, and the upper surface recesses and metal structures can correspond to the lower surface recesses and metal structures. The metal structures can be electrically coupled by plated structures positioned in the recesses.

A FinFET that includes a semiconductor substrate that has insulating areas, a fin structure, a gate dielectric layer, a gate electrode structure, a drain structure and a source structure is provided. The fin structure is disposed to extend on the semiconductor substrate between two insulating areas. The gate dielectric layer is disposed to extend across two sides of the fin structure. The gate electrode structure is disposed on the gate dielectric layer. The drain structure is disposed at a first side of the gate electrode structure and has a first resistance relative to the gate electrode. The source structure is disposed at a second side of the gate electrode structure and has a second resistance relative to the gate electrode. The first resistance is larger than the second resistance.

Methods and semiconductor structures are provided. A method according to the present disclosure includes receiving a workpiece that includes a first gate structure disposed over a first active region, a second gate structure disposed over a second active region, a first gate spacer extending along a sidewall of the first gate structure and disposed at least partially over a top surface of the first active region, a second gate spacer extending along a sidewall of the second gate structure and disposed at least partially over a top surface of the second active region, and a source/drain feature. The method also includes treating a portion of the first gate spacer and a portion of the second gate spacer with a remote radical of hydrogen or oxygen, removing the treated portions, and after the removal, depositing a metal fill material over the source/drain feature.

A device includes a semiconductor substrate. A step is formed at a periphery of the semiconductor substrate. A first layer, made of polysilicon doped in oxygen, is deposited on top of and in contact with a first surface of the substrate. This first layer extends at least on a wall and bottom of the step. A second layer, made of glass, is deposited on top of the first layer and the edges of the first layer. The second layer forms a boss between the step and a central area of the device.

What is provided is a field effect component including a semiconductor body, which extends in an edge zone from a rear side as far as a top side and which includes a semiconductor mesa, which extends in a vertical direction, which is perpendicular to the rear side and/or the top side. The semiconductor body in a vertical cross section further includes a drift region, which extends at least in the edge region as far as the top side and which is arranged partly in the semiconductor mesa, and a body region, which is arranged at least partly in the semiconductor mesa and which forms a pn junction with the drift region. The pn junction extends between two sidewalls of the semiconductor mesa.

A SiC semiconductor device includes a SiC chip having a main surface, a trench gate structure formed at the main surface, a trench source structure formed at the main surface away from the trench gate structure in one direction, an insulating film covering the trench gate structure and the trench source structure above the main surface, a gate main surface electrode formed on the insulating film and a gate wiring that is led out from the gate main surface electrode onto the insulating film such as to cross the trench gate structure and the trench source structure in the one direction, and that is electrically connected to the trench gate structure through the insulating film, and that faces the trench source structure with the insulating film between the trench source structure and the gate wiring.

Power devices using refilled trenches with permanent charge at or near their sidewalls. These trenches extend vertically into a drift region.