III-Nitride layers having spatially controlled regions or domains of porosities therein with tunable optical, electrical, and thermal properties are described herein. Also disclosed are methods for preparing and using such III-nitride layers.

A semiconductor body having a base carrier portion and a type III-nitride semiconductor portion is provided. The type III-nitride semiconductor portion includes a heterojunction and two-dimensional charge carrier gas. One or more ohmic contacts are formed in the type III-nitride semiconductor portion, the ohmic contacts forming an ohmic connection with the two-dimensional charge carrier gas. A gate structure is configured to control a conductive state of the two-dimensional charge carrier gas. Forming the one or more ohmic contacts comprises forming a structured laser-reflective mask on the upper surface of the type III-nitride semiconductor portion, implanting dopant atoms into the upper surface of the type III-nitride semiconductor portion, and performing a laser thermal anneal that activates the implanted dopant atoms.

An ion implanted region is formed by implanting Mg ions into a predetermined region of the surface of the first p-type layer. Subsequently, a second n-type layer is formed on the first p-type layer and the ion implanted region. A trench is formed by dry etching a predetermined region of the surface of the second n-type layer until reaching the first n-type layer. Next, heat treatment is performed to diffuse Mg. Thus, a p-type impurity region is formed in a region with a predetermined depth from the surface of the first n-type layer below the ion implanted region. Since the trench is formed before the heat treatment, Mg is not diffused laterally beyond the trench. Therefore, the width of the p-type impurity region is almost the same as the width of the first p-type layer divided by the trench.

A nitride semiconductor laminate includes: a substrate comprising a group III nitride semiconductor and including a surface and a reverse surface, the surface being formed from a nitrogen-polar surface, the reverse surface being formed from a group III element-polar surface and being provided on the reverse side from the surface; a protective layer provided at least on the reverse surface side of the substrate and having higher heat resistance than the reverse surface of the substrate; and a semiconductor layer provided on the surface side of the substrate and comprising a group III nitride semiconductor. The concentration of O in the semiconductor layer is lower than 1×10.sup.17 at/cm.sup.3.

A technique of improving the breakdown voltage of a semiconductor device is provided. There is provided a method of manufacturing a semiconductor device comprising a process of forming a p-type semiconductor layer that contains a p-type impurity and has a dislocation density of not higher than 1.0×10.sup.7 cm.sup.−2, on an n-type semiconductor layer that contains an n-type impurity and has a dislocation density of not higher than 1.0×10.sup.7 cm.sup.−2; an n-type semiconductor region forming process of forming an n-type semiconductor region in at least part of the p-type semiconductor layer by ion-implanting an n-type impurity into the p-type semiconductor layer and performing heat treatment to activate the ion-implanted n-type impurity; and a process of forming a trench that is recessed to pass through the p-type semiconductor layer and reach the n-type semiconductor layer. In the n-type semiconductor region forming process, a p-type impurity diffusion region in which the p-type impurity contained in the p-type semiconductor layer is diffused is formed in at least part of the n-type semiconductor layer that is located below the n-type semiconductor region.

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 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 1.0×10.sup.19 cm.sup.−3.

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 semiconductor body having a base carrier portion and a type III-nitride semiconductor portion is provided. The type III-nitride semiconductor portion includes a heterojunction and two-dimensional charge carrier gas. One or more ohmic contacts are formed in the type III-nitride semiconductor portion, the ohmic contacts forming an ohmic connection with the two-dimensional charge carrier gas. A gate structure is configured to control a conductive state of the two-dimensional charge carrier gas. Forming the one or more ohmic contacts comprises forming a structured laser-reflective mask on the upper surface of the type III-nitride semiconductor portion, implanting dopant atoms into the upper surface of the type III-nitride semiconductor portion, and performing a laser thermal anneal that activates the implanted dopant atoms.

The present disclosure provides a semiconductor device. The semiconductor device comprises a substrate, a plurality of isolation regions in the substrate and an active region surrounded by the isolation regions. A p-type doped region is interposed between two n-type doped regions in the substrate. A buried gate structure is formed in the substrate and disposed between the p-type doped region and the n-type doped region. The buried gate structure comprises a gate conductive material, a gate insulating layer disposed over the gate conductive material and a gate liner surrounding the gate conductive material and the gate insulating layer. A plurality of contact plugs are formed on the p-type doped region and the plurality of n-type doped regions.