A method for forming a semiconductor structure. Two isolation structures are formed in a semiconductor. A cavity is etched in the semiconductor between the two isolation structures in the semiconductor. Dopants are implanted into a bottom side of the cavity to form a doped region in the semiconductor below the cavity between the two isolation structures. A contact is formed in the cavity. The contact is on the doped region and in direct contact with the doped region.

A semiconductor substrate and a semiconductor device are disclosed. The semiconductor substrate includes a base layer, a buffer layer disposed on the base layer, a channel layer disposed on the buffer layer, a barrier layer disposed on the channel layer, and a buried field plate region embedded in the channel layer. In an embodiment, the channel layer includes a two-dimensional electron gas (2DEG), and the buried field plate region is located below the two-dimensional electron gas.

In an example, the present invention provides a method of forming a semiconductor device on a gallium and nitrogen containing material. The method includes providing a substrate member comprising a surface region, the substrate member comprising a gallium and nitrogen bearing material. The method includes causing an implanted species to electrically activate the implant profile while removing one or more crystalline damage from the epitaxial material to change the amorphous state to a single crystalline state, and thereby creating a substantially electrically activated crystalline material.

A method for manufacturing a vertical FET device includes providing a semiconductor substrate structure including a semiconductor substrate and a first semiconductor layer coupled to the semiconductor substrate. The first semiconductor layer is characterized by a first conductivity type. The method also includes forming a plurality of semiconductor fins coupled to the first semiconductor layer. Each of the plurality of semiconductor fins is separated by one of a plurality of recess regions. The method further includes epitaxially regrowing a semiconductor gate layer including a surface region in the plurality of recess regions. The method also includes forming an isolation region within the surface region of the semiconductor gate layer. The isolation region surrounds each of the plurality of semiconductor fins. The method includes forming a source contact structure coupled to each of the plurality of semiconductor fins and forming a gate contact structure coupled to the semiconductor gate layer.

A technique of reducing the complication in manufacture is provided. There is provided a semiconductor device comprising an n-type semiconductor region made of a nitride semiconductor containing gallium; a p-type semiconductor region arranged to be adjacent to and in contact with the n-type semiconductor region and made of the nitride semiconductor; a first electrode arranged to be in ohmic contact with the n-type semiconductor region; and a second electrode arranged to be in ohmic contact with the p-type semiconductor region. The first electrode and the second electrode are mainly made of one identical metal. The identical metal is at least one metal selected from the group consisting of palladium, nickel and platinum. A concentration of a p-type impurity in the n-type semiconductor region is approximately equal to a concentration of the p-type impurity in the p-type semiconductor region. A difference between a concentration of an n-type impurity and the concentration of the p-type impurity in the n-type semiconductor region is not less than 1.010.sup.19 cm.sup.3.

A technique of suppressing the potential crowding in the vicinity of the outer periphery of a bottom face of a trench without ion implantation of a p-type impurity is provided. A method of manufacturing a semiconductor device having a trench gate structure comprises an n-type semiconductor region forming process. In the n-type semiconductor region forming process, a p-type impurity diffusion region in which a p-type impurity contained in a p-type semiconductor layer is diffused is formed in at least part of an n-type semiconductor layer that is located below an n-type semiconductor region.

A method for manufacturing a semiconductor device comprises: a stacking process that stacks a p-type semiconductor layer of Group III nitride containing a p-type impurity on a first n-type semiconductor layer of Group III nitride containing an n-type impurity; a p-type ion implantation process that ion-implants the p-type impurity into the p-type semiconductor layer; and a heat treatment process that performs heat treatment to activate the ion-implanted p-type impurity. The p-type ion implantation process and the heat treatment process are performed such that the p-type impurity of the p-type semiconductor layer is diffused into the n-type semiconductor layer to form a first p-type impurity containing region in at least part of the first n-type semiconductor layer and below a region of the p-type semiconductor layer into which the ion implantation has been performed.

A technique that recovers from degradation in crystalline nature in an ion-implanted region is provided. A method of manufacturing a semiconductor device, includes: an ion implantation step of ion-implanting p-type impurities by a cumulative dose D into an n-type semiconductor layer containing n-type impurities; and a thermal annealing step of annealing an ion-implanted region of the n-type semiconductor layer where the p-type impurities are ion-implanted, in an atmosphere containing nitrogen, at a temperature T for a time t, wherein the cumulative dose D, the temperature T, and the time t satisfy a predetermined relationship.

The present application discloses a vertical UMOSFET device with a high channel mobility and a preparation method thereof. The vertical UMOSFET device with a high channel mobility includes an epitaxial structure, and a source, a drain and a gate which match the epitaxial structure, where the epitaxial structure includes a first semiconductor, and a second semiconductor and a third semiconductor which are sequentially disposed on the first semiconductor, a groove structure matching the gate is also disposed in the epitaxial structure, and the groove structure continuously extends into the first semiconductor from a first surface of the epitaxial structure; a fourth semiconductor is also disposed at least between an inner wall of the groove structure and the second semiconductor, and the fourth semiconductor is a high resistivity semiconductor.

A manufacturing process provides for: forming a semiconductor body of silicon carbide, having a front surface; performing a localized ion implantation to form implanted regions in implant portions in the semiconductor body. The step of performing a localized ion implantation provides for: forming damaged regions at the front surface, separated from each other by the implant portions in a direction parallel to the front surface; performing a channeled ion implantation, for implanting doping ions within the semiconductor body and forming the implanted regions at the implant portions of the semiconductor body. The channeled ion implantation is performed in a self-aligned manner with respect to the damaged regions, which represent damaged regions of the silicon-carbide crystallographic lattice such as to block a propagation of the channeled ion implantation along a vertical axis orthogonal to the front surface, in a depth direction of the semiconductor body.