A method for manufacturing a semiconductor device includes the steps of forming a first insulating film over a first gate electrode over a substrate while heated at a temperature higher than or equal to 450 C. and lower than the strain point of the substrate, forming a first oxide semiconductor film over the first insulating film, adding oxygen to the first oxide semiconductor film and then forming a second oxide semiconductor film over the first oxide semiconductor film, and performing heat treatment so that part of oxygen contained in the first oxide semiconductor film is transferred to the second oxide semiconductor film.

Devices, and methods of forming such devices, having a material that is semimetal when in bulk but is a semiconductor in the devices are described. An example structure includes a substrate, a first source/drain contact region, a channel structure, a gate dielectric, a gate electrode, and a second source/drain contact region. The substrate has an upper surface. The channel structure is connected to and over the first source/drain contact region, and the channel structure is over the upper surface of the substrate. The channel structure has a sidewall that extends above the first source/drain contact region. The channel structure comprises a bismuth-containing semiconductor material. The gate dielectric is along the sidewall of the channel structure. The gate electrode is along the gate dielectric. The second source/drain contact region is connected to and over the channel structure.

A method for forming a semiconductor device includes forming a first insulator layer on a first substrate of a first semiconductor material, implanting hydrogen ions into the first substrate to form a hydrogen-implanted layer, forming a recessed region in the first substrate, forming a second semiconductor material in the recessed region, and forming a second insulator layer over the second semiconductor material and the first substrate. The method also includes providing a second substrate with a third insulator layer disposed thereon, bonding the first substrate with the second substrate, and removing a lower portion of the first substrate at the hydrogen-implanted layer. A portion of the first substrate is removed to expose a surface of the second semiconductor material in the recessed region, thereby providing a layer of the first semiconductor material adjacent to a layer of the second semiconductor material on the second insulator layer.

A semiconductor structure includes a first device and a second device. The first device has a first surface. The first device includes a first active region defined by a first material system. The second device has a second surface. The second surface is coplanar with the first surface. The second device includes a second active region defined by a second material system. The second material system is different from the first material system.

A miniaturized transistor is provided. A transistor with low parasitic capacitance is provided. A transistor having high frequency characteristics is provided. A transistor having a large amount of on-state current is provided. A semiconductor device including the transistor is provided. A semiconductor device with high integration is provided. A novel capacitor is provided. The capacitor includes a first conductor, a second conductor, and an insulator. The first conductor includes a region overlapping with the second conductor with the insulator provided therebetween. The first conductor includes tungsten and silicon. The insulator includes a silicon oxide film that is formed by oxidizing the first conductor.

Method for fabricating a semiconductor structure. The method includes: providing a crystalline silicon substrate; defining an opening in a dielectric layer on the crystalline silicon substrate, the opening having sidewalls and a bottom wherein the bottom corresponds to a surface of the crystalline silicon substrate; providing a confinement structure above the dielectric layer, thereby forming a confinement region between the confinement structure and the dielectric layer; and growing a crystalline compound semiconductor material in the confinement region thereby at least partially filling the confinement region. The present invention also provides an improved compound semiconductor structure and a device for fabricating such semiconductor structure.

A device includes a crystalline material within an area confined by an insulator. In one embodiment, the area confined by the insulator is an opening in the insulator having an aspect ratio sufficient to trap defects using an ART technique. Method and apparatus embodiments of the invention can reduce edge effects in semiconductor devices. Embodiments of the invention can provide a planar surface over a buffer layer between a plurality of uncoalesced ART structures.

To provide a semiconductor device having large memory capacity and high reliability of data or a small-size semiconductor device having a small circuit area. A memory cell includes first and second data retention portions capable of storing multilevel data. A data voltage is written to the first data retention portion from a first wiring through a transistor and a second wiring, and a data voltage is written to the second data retention portion from the second wiring through a transistor and the first wiring. With the configuration, data voltages reduced by the threshold voltages of the transistors can be retained in the first and second data retention portions. The written data voltages where the threshold voltages of the transistors are canceled can be read by precharging and then discharging the first wiring.

A trench comprising a portion of a substrate is formed. A nucleation layer is deposited on the portion of the substrate within the trench. A III-N material layer is deposited on the nucleation layer. The III-N material layer is laterally grown over the trench. A device layer is deposited on the laterally grown III-N material layer. A low defect density region is obtained on the laterally grown material and is used for electronic device fabrication of III-N materials on Si substrates.

Trench-confined selective epitaxial growth process in which epitaxial growth of a semiconductor device layer proceeds within the confines of a trench. In embodiments, a trench is fabricated to include a pristine, planar semiconductor seeding surface disposed at the bottom of the trench. Semiconductor regions around the seeding surface may be recessed relative to the seeding surface with Isolation dielectric disposed there on to surround the semiconductor seeding layer and form the trench. In embodiments to form the trench, a sacrificial hardmask fin may be covered in dielectric which is then planarized to expose the hardmask fin, which is then removed to expose the seeding surface. A semiconductor device layer is formed from the seeding surface through selective heteroepitaxy. In embodiments, non-planar devices are formed from the semiconductor device layer by recessing a top surface of the isolation dielectric. In embodiments, non-planar devices CMOS devices having high carrier mobility may be made from the semiconductor device layer.