A GaN-based high electron mobility transistor (HEMT) device includes a semiconductor structure comprising a channel layer and a barrier layer sequentially stacked on a substrate, a drain contact and a source contact on the barrier layer, and a gate contact on the barrier layer between the drain contact and the source contact. A sheet resistance of a drain access region and/or a source access region of the semiconductor structure is between 300 and 400 Ω/sq.

A III-nitride-based semiconductor wafer is provided that includes a substrate with a central region and a peripheral edge region. One or more intermediate layers may be optionally provided selected from a buffer layer, a seed layer, or a transition layer. A peripheral edge feature is formed in or on a peripheral edge region of the substrate or the transition layer, with one or more peripheral edge passivation layers or peripheral edge surface texturing. The peripheral edge feature extends only around the peripheral edge and not in the central region. One or more III-nitride-based layers is positioned over the central region. In the central region, the III-nitride layer is an epitaxial layer while in the peripheral edge region, it is a polycrystalline layer. Stress due to lattice mismatches and differences in the coefficient of thermal expansion between the III-nitride layer and the substrate is relieved, minimizing defects.

A III-nitride-based semiconductor wafer is provided that includes a substrate with a central region and a peripheral edge region. One or more intermediate layers may be optionally provided selected from a buffer layer, a seed layer, or a transition layer. A peripheral edge feature is formed in or on a peripheral edge region of the substrate or the transition layer, with one or more peripheral edge passivation layers or peripheral edge surface texturing. The peripheral edge feature extends only around the peripheral edge and not in the central region. One or more III-nitride-based layers is positioned over the central region. In the central region, the III-nitride layer is an epitaxial layer while in the peripheral edge region, it is a polycrystalline layer. Stress due to lattice mismatches and differences in the coefficient of thermal expansion between the III-nitride layer and the substrate is relieved, minimizing defects.

A method includes depositing a mask layer over a semiconductor substrate, etching the mask layer to form a patterned mask, wherein a sidewall of the patterned mask includes a first sidewall region, a second sidewall region, and a third sidewall region, wherein the first sidewall region is farther from the semiconductor substrate than the second sidewall region and the second sidewall region is farther from the semiconductor substrate than the third sidewall region, wherein the second sidewall region protrudes laterally from the first sidewall region and from the third sidewall region, etching the semiconductor substrate using the patterned mask to form fins, forming a gate stack over the fins, and forming source and drain regions in the fin adjacent the gate stack.

A method produces a single-crystal silicon semiconductor wafer. A single-crystal silicon substrate wafer is double side polished. A front side of the substrate wafer is chemical mechanical polished (CMP). An epitaxial layer of single-crystal silicon is deposited on the front side of the substrate wafer. A first rapid thermal anneal (RTA) treatment is performed on the coated substrate wafer at 1275-1295° C. for 15-30 seconds in argon and oxygen, having oxygen of 0.5-2.0 vol %. The coated substrate wafer is then cooled at or below 800° C., with 100 vol % argon. A second RTA treatment is performed on the coated substrate wafer at a 1280-1300° C. for 20-35 seconds in argon. An oxide layer is removed from a front side of the coated substrate wafer. The front side of the coated substrate wafer is polished by CMP.

A method produces a single-crystal silicon semiconductor wafer. A single-crystal silicon substrate wafer is double side polished. A front side of the substrate wafer is chemical mechanical polished (CMP). An epitaxial layer of single-crystal silicon is deposited on the front side of the substrate wafer. A first rapid thermal anneal (RTA) treatment is performed on the coated substrate wafer at 1275-1295° C. for 15-30 seconds in argon and oxygen, having oxygen of 0.5-2.0 vol %. The coated substrate wafer is then cooled at or below 800° C., with 100 vol % argon. A second RTA treatment is performed on the coated substrate wafer at a 1280-1300° C. for 20-35 seconds in argon. An oxide layer is removed from a front side of the coated substrate wafer. The front side of the coated substrate wafer is polished by CMP.

A semiconductor device includes an SiC semiconductor layer which has a first main surface on one side and a second main surface on the other side, a semiconductor element which is formed in the first main surface, a raised portion group which includes a plurality of raised portions formed at intervals from each other at the second main surface and has a first portion in which some of the raised portions among the plurality of raised portions overlap each other in a first direction view as viewed in a first direction which is one of the plane directions of the second main surface, and an electrode which is formed on the second main surface and connected to the raised portion group.

A silicon carbide semiconductor device includes: a silicon carbide layer of a first conductive type including a defect region in which a crystal defect exists; a plurality of well regions of a second conductive type formed on the silicon carbide layer; source regions of the first conductive type formed in the well regions; gate oxide films formed on the silicon carbide layer, the well regions and the source regions; gate electrodes formed on the gate oxide films; and a source electrode electrically connected to the well regions and the source regions, wherein the source region is not formed in the defect region.

A layer of a crystal of a group 13 nitride selected from gallium nitride, aluminum nitride, indium nitride and the mixed crystals thereof has an upper surface and a bottom surface. The upper surface of a crystal layer of the group 13 nitride includes a linear high-luminance light-emitting part and a low-luminance light-emitting region adjacent to the high-luminance light-emitting part, observed by cathode luminescence. The high-luminance light-emitting part includes a portion extending along an m-plane of the crystal of the group 13 nitride. The crystal of the nitride of the group 13 element contains oxygen atoms in a content of 1×10.sup.18 atom/cm.sup.3 or less, silicon atoms, manganese atoms, carbon atoms, magnesium atoms and calcium atoms in contents of 1×10.sup.17 atom/cm.sup.3 or less, chromium atoms in a content of 1×10.sup.16 atom/cm.sup.3 or less and chlorine atoms in a content of 1×10.sup.15 atom/cm.sup.3 or less.

A layer of a crystal of a group 13 nitride selected from gallium nitride, aluminum nitride, indium nitride and the mixed crystals thereof has an upper surface and a bottom surface. The upper surface of a crystal layer of the group 13 nitride includes a linear high-luminance light-emitting part and a low-luminance light-emitting region adjacent to the high-luminance light-emitting part, observed by cathode luminescence. The high-luminance light-emitting part includes a portion extending along an m-plane of the crystal of the group 13 nitride. The crystal of the nitride of the group 13 element contains oxygen atoms in a content of 1×10.sup.18 atom/cm.sup.3 or less, silicon atoms, manganese atoms, carbon atoms, magnesium atoms and calcium atoms in contents of 1×10.sup.17 atom/cm.sup.3 or less, chromium atoms in a content of 1×10.sup.16 atom/cm.sup.3 or less and chlorine atoms in a content of 1×10.sup.15 atom/cm.sup.3 or less.