A semiconductor device includes a barrier layer, a dielectric layer, a first protection layer, a first spacer, and a gate. The dielectric layer is disposed on the barrier layer. The first protection layer is disposed on the barrier layer, in which the first protection layer extends from a first sidewall of the dielectric layer to a top surface of the barrier layer. The first spacer is disposed on and received by the first protection layer, in which a top end of the first protection layer comprises a first curved surface between the first spacer and the dielectric layer. The gate is disposed on the barrier layer, the dielectric layer, and the first spacer. The gate extends from a top surface of the dielectric layer and at least along the first curved surface of the first protection layer to make contact with the top surface of the barrier layer.

In an embodiment, a Group III nitride device includes a multilayer Group III nitride structure and a first ohmic contact arranged on and forming an ohmic contact to the multilayer Group III nitride device structure. The first ohmic contact includes a base portion having a conductive surface, the conductive surface including a peripheral portion and a central portion, the peripheral portion and the central portion being substantially coplanar and being of differing composition, a conductive via positioned on the central portion of the conductive surface and a contact pad positioned on the conductive via.

An ohmic contact includes a first semiconductor layer a second semiconductor layer, and a heterointerface between the first semiconductor layer and the second semiconductor layer. The second semiconductor layer has a two-dimensional electron sheet region in which a two-dimensional electron sheet is formed. The ohmic contact further includes a metal terminal covering the first semiconductor layer and filling a plurality of direct access pathways that provide direct lateral contact with the two-dimensional electron sheet region. The semiconductor device is fabricated by providing the semiconductor layers, etching the direct access pathways, and depositing metal material to fill the direct access pathways and cover the semiconductor layers. The ohmic contact may be part of a high-electron-mobility transistor that achieves low contact resistance with either no annealing at all (as-deposited metal), or at an anneal temperature that is much lower than industry-standard anneal temperatures to achieve sufficiently low contact resistance.

The present disclosure provides a semiconductor device and a method for manufacturing the same, and it relates to a field of semiconductor technology. The semiconductor device includes a substrate, a semiconductor layer, a dielectric layer, a source, a drain, and a gate, wherein a first face of the gate close to a side of the drain and close to the semiconductor layer has a first curved face. A gate trench corresponding to the gate is provided on the dielectric layer, a material of the gate being filled in the gate trench, and at least a part of a second face of the gate trench in contact with the gate is a second curved face which extends from a surface of the dielectric layer away from the semiconductor layer toward the semiconductor layer.

N-polar transistor structures have relied on the use of dry etch processes that use plasmas generated from gaseous species to remove III-N layers as commercially viable wet etchants do not exist. The present disclosure reports on methods for the fabrication of N-polar III-N transistors using wet etches along with transistor structures that are enabled by the availability of wet-etches.

A high electron mobility transistor includes a substrate, a semiconductor channel layer, a semiconductor barrier layer, a gate field plate, a source electrode, at least one first field plate, and a second field plate. The gate field plate is disposed on the semiconductor barrier layer. The source electrode is disposed on one side of the gate field plate, and the first field plate is disposed on the other side of the gate field plate and laterally spaced apart from the gate field plate. The second field plate covers the gate field plate and the first field plate and is electrically connected to the source electrode, where the area of the second field plate is larger than the sum of the area of the gate field plate and the area of the first field plate when perceived from a top-down perspective.

Semiconductor device includes a semiconductor layer, an insulating film provided on the semiconductor layer and having an opening formed therein, a gate electrode connected to the semiconductor layer through opening, a protection film covering gate electrode, and a Ni oxide film, wherein the insulating film has a first surface on the semiconductor layer side and a second surface opposite to the first surface, and the gate electrode has a third surface facing the second surface and spaced apart from the second surface and a fourth surface connecting the second surface and the third surface. The gate electrode includes a Ni film constituting the third surface and the fourth surface, and the Ni oxide film covers the Ni film on the third surface and the fourth surface. The protection film covers the third surface and the fourth surface by being placed over Ni oxide film.

A method of fabricating a gate with a mini field plate includes forming a dielectric passivation layer over an epitaxy layer on a substrate, coating the dielectric passivation layer with a first resist layer, etching the first resist layer and the dielectric passivation layer to form a first opening in the dielectric passivation layer, removing the first resist layer; and forming a tri-layer gate having a gate foot in the first opening, the gate foot having a first width, a gate neck extending from the gate foot and extending for a length over the dielectric passivation layer on both sides of the first opening, the gate neck having a second width wider than the first width of the gate foot, and a gate head extending from the gate neck, the gate head having a third width wider than the second width of the gate neck.

The present disclosure provides a semiconductor device and a fabrication method thereof. The semiconductor device includes a III-V material layer and a gate structure. The gate structure includes a first portion and a second portion on the first portion. The first portion is on the III-V material layer. The first portion has a first surface and a second surface opposite to the first surface and adjacent to the III-V material layer. A length of the second surface of the first portion of the gate structure is less than a length of the first surface of the first portion of the gate structure. A length of the second portion of the gate structure is less than the length of the first portion of the gate structure.

In an embodiment, a Group III nitride device includes a multilayer Group III nitride structure and a first ohmic contact arranged on and forming an ohmic contact to the multilayer Group III nitride device structure. The first ohmic contact includes a base portion having a conductive surface, the conductive surface including a peripheral portion and a central portion, the peripheral portion and the central portion being substantially coplanar and being of differing composition, a conductive via positioned on the central portion of the conductive surface and a contact pad positioned on the conductive via.