A method of manufacturing a silicon carbide semiconductor device. The method includes epitaxially growing an epitaxial layer on a starting substrate to form a semiconductor wafer, forming a plurality of scribe lines, including a first scribe line, in the epitaxial layer, forming a mark in the first scribe line, inspecting the epitaxial layer for a crystal defect using crystal defect inspection equipment, which recognizes the first scribe line as being a second scribe line, forming a device element structure in the semiconductor wafer, dicing the semiconductor wafer into semiconductor chips along the scribe lines, and identifying, as a conforming product candidate, one of the semiconductor chips that is free of the crystal defect detected during the inspecting. A distance between an edge of the second scribe line and an edge of the mark, when the first and second scribe lines are aligned, is in a range from 10 μm to 25 μm.

A method includes forming a fin that includes a first semiconductor layers and a second semiconductor layers alternatively disposed; forming a gate stack on the fin and a gate spacer disposed on a sidewall of the gate stack; etching the fin within a source/drain region, resulting in a source/drain trench; recessing the first semiconductor layers in the source/drain trench, resulting in first recesses underlying the gate spacer; forming inner spacers in the first recesses; recessing the second semiconductor layers in the source/drain trench, resulting in second recesses; and epitaxially growing a source/drain feature in the source/drain trench, wherein the epitaxially growing further includes a first epitaxial semiconductor layer extending into the second recesses; and a second epitaxial semiconductor layer on the first epitaxial semiconductor layer and filling in the source/drain trench, wherein the first and second epitaxial semiconductor layers are different in composition.

A silicon carbide semiconductor device including a silicon carbide semiconductor substrate. The silicon carbide semiconductor substrate has an active region through which a main current flows, and a termination region surrounding a periphery of the active region in a top view of the silicon carbide semiconductor device. In the top view, the active region is of a rectangular shape, which has two first sides in a <11-20> direction and two second sides in a <1-100> direction. The two first sides are each of a first length, and the two second sides are each of a second length, the first length being longer than the second length.

Provided is a field effect transistor including a gate insulating layer having a two-dimensional material. The field effect transistor may include a first channel layer; a second channel layer disposed on the first channel layer; a gate insulating layer disposed on the second channel layer; a gate electrode disposed on the gate insulating layer; a first electrode electrically connected to the first channel layer; and a second electrode electrically connected to the second channel layer. Here, the gate insulating layer may include an insulative, high-k, two-dimensional material.

The present disclosure provides a FinFET device. The FinFET device comprises a semiconductor substrate of a first semiconductor material; a fin structure of the first semiconductor material overlying the semiconductor substrate, wherein the fin structure has a top surface of a first crystal plane orientation; a diamond-like shape structure of a second semiconductor material disposed over the top surface of the fin structure, wherein the diamond-like shape structure has at least one surface of a second crystal plane orientation; a gate structure disposed over the diamond-like shape structure, wherein the gate structure separates a source region and a drain region; and a channel region defined in the diamond-like shape structure between the source and drain regions.

Provided are a semiconductor device and a method for manufacturing same. The device comprises: a substrate, a first insulating layer on the substrate, a plurality of trenches formed in the substrate, a nucleation layer arranged on one side wall of each trench, and a first semiconductor layer formed along the trenches by means of the nucleation layer. The present disclosure facilitates the achievement of one of the following effects: achieving a high height-width ratio and a high integration density, reducing an on-resistance, improving a threshold voltage, achieving a normally-off state, and providing a semiconductor device that has a high power and a high reliability, is suitable for a planarization process, is provided with an easy preparation method, and reduces costs.

A semiconductor apparatus includes a first semiconductor layer, a second semiconductor layer overlapping the first semiconductor layer, and a wiring structure arranged between them. The second semiconductor layer is provided with p-type MIS transistor. A crystal structure of the first semiconductor layer has a first crystal orientation and a second crystal orientation in direction along a principal surface of the first semiconductor layer. A Young's modulus of the first semiconductor layer in a direction along the first crystal orientation is higher than that in a direction along the second crystal orientation. An angle formed by the first crystal orientation and a direction in which a source and a drain of the p-type MIS transistor are arranged is more than 30 degrees and less than 60 degrees, and an angle formed by the second crystal orientation and that direction is 0 degrees or more and 30 degrees or less.

A method includes forming a first fin and a second fin over a substrate, depositing an isolation material surrounding the first and second fins, forming a gate structure along sidewalls and over upper surfaces of the first and second fins, recessing the first and second fins outside of the gate structure to form a first recess in the first fin and a second recess in the second fin, epitaxially growing a first source/drain material protruding from the first and second recesses, and epitaxially growing a second source/drain material on the first source/drain material, wherein the second source/drain material grows at a slower rate on outermost surfaces of opposite ends of the first source/drain material than on surfaces of the first source/drain material between the opposite ends of the first source/drain material, and wherein the second source/drain material has a higher doping concentration than the first source/drain material.

A device includes a first fin and a second fin extending from a substrate, the first fin including a first recess and the second fin including a second recess, an isolation region surrounding the first fin and surrounding the second fin, a gate stack over the first fin and the second fin, and a source/drain region in the first recess and in the second recess, the source/drain region adjacent the gate stack, wherein the source/drain region includes a bottom surface extending from the first fin to the second fin, wherein a first portion of the bottom surface that is below a first height above the isolation region has a first slope, and wherein a second portion of the bottom surface that is above the first height has a second slope that is greater than the first slope.

A layered structure including a substrate in [100] crystal orientation, a crystalline bixbyite oxide layer in [111] orientation, and a metal-containing layer crystallographically matched to the crystalline bixbyite oxide layer. Advantageously a high quality metal-containing layer can be grown on a substrate, which is common across the industry and which opens integration and cost benefits.