An inertial sensor includes: a substrate; an insulating film provided on a main surface of the substrate; a first semiconductor layer and a second semiconductor layer which are provided on an opposite-side surface of the insulating film from the substrate; a first oxide film provided on a first side surface of the first semiconductor layer on a second semiconductor layer side; a second oxide film provided on a second side surface of the second semiconductor layer on a first semiconductor layer side; a planarization insulating film provided above the first oxide film and the second oxide film and between the first oxide film and the second oxide film; and a wiring provided on the planarization insulating film and electrically coupled to the second semiconductor layer.

Embodiments disclosed herein relate generally to capping processes and structures formed thereby. In an embodiment, a conductive feature, formed in a dielectric layer, has a metallic surface, and the dielectric layer has a dielectric surface. The dielectric surface is modified to be hydrophobic by performing a surface modification treatment. After modifying the dielectric surface, a capping layer is formed on the metallic surface by performing a selective deposition process. In another embodiment, a surface of a gate structure is exposed through a dielectric layer. A capping layer is formed on the surface of the gate structure by performing a selective deposition process.

Methods of forming semiconductor devices are provided. One of the methods includes following steps. A plurality of hard mask patterns is formed around a region of a substrate, wherein an imaginary connecting line is formed between corners of two of the plurality of hard mask patterns at the same side of the region, and the imaginary connecting line is substantially parallel to or perpendicular to a horizontal direction. A semiconductor layer is formed on the substrate by a selective epitaxial growth process.

Embodiments disclosed herein relate generally to capping processes and structures formed thereby. In an embodiment, a conductive feature, formed in a dielectric layer, has a metallic surface, and the dielectric layer has a dielectric surface. The dielectric surface is modified to be hydrophobic by performing a surface modification treatment. After modifying the dielectric surface, a capping layer is formed on the metallic surface by performing a selective deposition process. In another embodiment, a surface of a gate structure is exposed through a dielectric layer. A capping layer is formed on the surface of the gate structure by performing a selective deposition process.

Embodiments disclosed herein relate generally to capping processes and structures formed thereby. In an embodiment, a conductive feature, formed in a dielectric layer, has a metallic surface, and the dielectric layer has a dielectric surface. The dielectric surface is modified to be hydrophobic by performing a surface modification treatment. After modifying the dielectric surface, a capping layer is formed on the metallic surface by performing a selective deposition process. In another embodiment, a surface of a gate structure is exposed through a dielectric layer. A capping layer is formed on the surface of the gate structure by performing a selective deposition process.

An integrated circuit device includes a portion of a support wafer (e.g., a handle wafer), silicon on insulator layer, a first active device, and a second active device. The first active device has a first semiconductor thickness in a dielectric layer (e.g., a buried oxide layer). The first active device is on the SOI layer. The second active device has a second semiconductor thickness in the same dielectric layer as the first active device. The supporting wafer supports the first active device and the second active device. The second active device is also on the SOI layer. The first and second thicknesses are different from one another.

Methods are provided for fabricating semiconductor nanowires on a substrate. A nanowire template is formed on the substrate. The nanowire template defines an elongate tunnel which extends, laterally over the substrate, between an opening in the template and a seed surface. The seed surface is exposed to the tunnel and of an area up to about 210.sup.4 nm.sup.2. The semiconductor nanowire is selectively grown, via said opening, in the template from the seed surface. The area of the seed surface is preferably such that growth of the nanowire proceeds from a single nucleation point on the seed surface. There is also provided a method for fabricating a plurality of semiconductor nanowires on a substrate and a semiconductor nanowire and substrate structure.

Provided are a device substrate with high thermal conductivity, with high heat dissipation, and with a small loss at high frequencies, and a method of manufacturing the device substrate. A device substrate 1 of the present invention can be manufactured by: provisionally bonding a Si device layer side of an SOI device substrate 10 to a support substrate 20 using a provisional bonding adhesive 31, the SOI device substrate including a Si base substrate 11, a Box layer 12 formed on the Si base substrate, having high thermal conductivity, and being an electrical insulator, and a Si device layer 13 formed on the Box layer; removing the Si base substrate 11 of the provisionally bonded SOI device substrate until the Box layer is exposed, thereby obtaining a thinned device wafer 10a; transfer-bonding the Box layer side of the thinned device wafer and a transfer substrate 40 to each other using a transfer adhesive 32 having a heat-resistant temperature of at least 150 C. by applying heat and pressure, the transfer substrate having high thermal conductivity and being an electrical insulator; and separating the support substrate 20.

The present disclosure relates to semiconductor structures and, more particularly, to oxidized cavity structures within and under semiconductor devices and methods of manufacture. The structure includes: a substrate material; active devices over the substrate material; an oxidized trench structure extending into the substrate and surrounding the active devices; and one or more oxidized cavity structures extending from the oxidized trench structure and formed in the substrate material under the active devices.

Methods of forming semiconductor devices are provided. One of the methods includes following steps. A plurality of hard mask patterns is formed around a region of a substrate, wherein an imaginary connecting line is formed between corners of two of the plurality of hard mask patterns at the same side of the region, and the imaginary connecting line is substantially parallel to or perpendicular to a horizontal direction. A semiconductor layer is formed on the substrate by a selective epitaxial growth process.