In a method for semiconductor processing, a semiconductor substrate is provided. The semiconductor substrate defines at least one first trench therein. The at least one first trench has a first depth (d.sub.1). A coating layer is deposited onto the semiconductor substrate using at least one precursor under a setting for a processing temperature (T). The coating layer defines at least one second trench having a second depth (d.sub.2) above the at least one first trench. A first depth parameter (t) of the second depth (d.sub.2) relative to the first depth (d.sub.1) is determined. The processing temperature (T) is then determined based on the first depth parameter (t).

A topology-selective deposition method is disclosed. An exemplary method includes providing an inhibition agent comprising a first nitrogen-containing gas, providing a deposition promotion agent comprising a second nitrogen-containing gas to form an activated surface on one or more of a top surface, a bottom surface, and a sidewall surface relative to one or more of the other of the top surface, the bottom surface, and the sidewall surface, and providing a precursor to react with the activated surface to thereby selectively form material comprising a nitride on the activated surface.

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.

The present disclosure relates to a part including silicon carbide layer and manufacturing method thereof, and the manufacturing method according to the present disclosure includes preparing a graphite substrate, and laminating a silicon carbide layer on a surface of the graphite substrate, wherein at the laminating the silicon carbide layer, the silicon carbide layer is laminated such that the thickness of the silicon carbide layer is 0.01 to 1 times the thickness of the graphite substrate, thereby improving the durability of the part including silicon carbide layer.

Various embodiments of the present disclosure are directed towards a method for forming an image sensor in which a device layer has high crystalline quality. According to some embodiments, a hard mask layer is deposited covering a substrate. A first etch is performed into the hard mask layer and the substrate to form a cavity. A second etch is performed to remove crystalline damage from the first etch and to laterally recess the substrate in the cavity so the hard mask layer overhangs the cavity. A sacrificial layer is formed lining cavity, a blanket ion implantation is performed into the substrate through the sacrificial layer, and the sacrificial layer is removed. An interlayer is epitaxially grown lining the cavity and having a top surface underlying the hard mask layer, and a device layer is epitaxially grown filling the cavity over the interlayer. A photodetector is formed in the device layer.

The present disclosure provides a radio frequency device, a silicon carbide homoepitaxial substrate and a manufacturing method thereof. The manufacturing method of the silicon carbide homoepitaxial substrate includes: providing an N-type silicon carbide substrate, forming first grooves in the N-type silicon carbide substrate; forming a defect repair layer on inner walls of the first grooves and outside the first grooves, and forming second grooves in the defect repair layer corresponding to the first grooves; forming an unintentionally doped silicon carbide layer on the defect repair layer, where the second grooves are fully filled with the unintentionally doped silicon carbide layer.

Gallium nitride (GaN) epitaxy on patterned substrates for integrated circuit technology is described. In an example, an integrated circuit structure includes a material layer including gallium and nitrogen, the material layer having a first side and a second side opposite the first side. A plurality of fins is on the first side of the material layer, the plurality of fins including silicon. A device layer is on the second side of the material layer, the device layer including one or more GaN-based devices.

A semiconductor device has a substrate. The substrate can be multiple layers. A first semiconductor layer made of a first semiconductor material is disposed over the substrate. The first semiconductor material can be substantially defect-free silicon carbide. A second semiconductor layer made of a second semiconductor material dissimilar from the first semiconductor material is disposed over the first semiconductor layer. The second semiconductor material is silicon. A third layer can be disposed between the first semiconductor layer and second semiconductor layer. A semiconductor device is formed in the second semiconductor layer. The semiconductor device can be a power MOSFET or diode. The second semiconductor layer with the electrical component provides a first portion of a breakdown voltage for the semiconductor device and the first semiconductor layer and substrate provide a second portion of the breakdown voltage for the semiconductor device.

Gallium nitride (GaN) selective epitaxial windows for integrated circuit technology is described. In an example, an integrated circuit structure includes a substrate including silicon, the substrate having a top surface. A first trench is in the substrate, the first trench having a first width and a first height. A second trench is in the substrate, the second trench having a second width and a second height. The second width is greater than the first width, and the second height is greater than the first height. A first island is in the first trench, the first island including gallium and nitrogen and having first corner facets at least partially below the top surface of the substrate. A second island is in the second trench, the second island including gallium and nitrogen and having second corner facets at least partially below the top surface of the substrate.

A semiconductor device has a substrate made of a first semiconductor material. The first semiconductor material is silicon carbide. A first semiconductor layer made of the first semiconductor material is disposed over the substrate. A second semiconductor layer made of a second semiconductor material dissimilar from the first semiconductor material is disposed over the first semiconductor layer. The first semiconductor material is substantially defect-free silicon carbide, and the second semiconductor material is silicon. A semiconductor device is formed in the second semiconductor layer. The semiconductor device can be a power MOSFET, diode, insulated gate bipolar transistor, cluster trench insulated gate bipolar transistor, and thyristor. The second semiconductor layer with the electrical component provides a first portion of a breakdown voltage for the semiconductor device and the first semiconductor layer and substrate provide a second portion of the breakdown voltage for the semiconductor device.