An electrical device comprising a base semiconductor layer of a silicon including material; a dielectric layer present on the base semiconductor layer; a first III-V semiconductor material area present in a trench in the dielectric layer, wherein a via of the III-V semiconductor material extends from the trench through the dielectric layer into contact with the base semiconductor layer; a second semiconductor material area present in the trench in the dielectric layer wherein the second III-V semiconductor material area does not have a via extending through the dielectric layer into contact with the base semiconductor layer; and a semiconductor device present on the second III-V semiconductor material area, wherein the first III-V semiconductor material area and the second III-V semiconductor material area are separated by a low aspect ratio trench extending to the dielectric layer.

An electrical device comprising a base semiconductor layer of a silicon including material; a dielectric layer present on the base semiconductor layer; a first III-V semiconductor material area present in a trench in the dielectric layer, wherein a via of the III-V semiconductor material extends from the trench through the dielectric layer into contact with the base semiconductor layer; a second semiconductor material area present in the trench in the dielectric layer wherein the second III-V semiconductor material area does not have a via extending through the dielectric layer into contact with the base semiconductor layer; and a semiconductor device present on the second III-V semiconductor material area, wherein the first III-V semiconductor material area and the second III-V semiconductor material area are separated by a low aspect ratio trench extending to the dielectric layer.

An object is to provide a semiconductor device having good electrical characteristics. A gate insulating layer having a hydrogen concentration less than 610.sup.20 atoms/cm.sup.3 and a fluorine concentration greater than or equal to 110.sup.20 atoms/cm.sup.3 is used as a gate insulating layer in contact with an oxide semiconductor layer forming a channel region, so that the amount of hydrogen released from the gate insulating layer can be reduced and diffusion of hydrogen into the oxide semiconductor layer can be prevented. Further, hydrogen present in the oxide semiconductor layer can be eliminated with the use of fluorine; thus, the hydrogen content in the oxide semiconductor layer can be reduced. Consequently, the semiconductor device having good electrical characteristics can be provided.

A low noise infrared photodetector has an epitaxial heterostructure that includes a photodiode and a transistor. The photodiode includes a high sensitivity narrow bandgap photodetector layer of first conductivity type, and a collection well of second conductivity type in contact with the photodetector layer. The transistor includes the collection well, a transfer well of second conductivity type that is spaced from the collection well and the photodetector layer, and a region of first conductivity type between the collection and transfer wells. The collection well and the transfer well are of different depths, and are formed by a single diffusion.

A method of forming a semiconductor structure includes forming a gate structure having a first conductive material above a semiconductor substrate, gate spacers on opposing sides of the first conductive material, and a first interlevel dielectric (ILD) layer surrounding the gate spacers and the first conductive material. An upper portion of the first conductive material is recessed. The gate spacers are recessed until a height of the gate spacers is less than a height of the gate structure. An isolation liner is deposited above the gate spacers and the first conductive material. A portion of the isolation liner is removed so that a top surface of the first conductive material is exposed. A second conductive material is deposited in a contact hole created above the first conductive material and the gate spacers to form a gate contact.

A semiconductor device is provided as follows. Active fins protrude from a substrate, extending in a first direction. A first device isolation layer is disposed at a first side of the active fins. A second device isolation layer is disposed at a second side of the active fins. A top surface of the second device isolation layer is higher than a top surface of the first device isolation layer and the second side is opposite to the first side. A normal gate extends across the active fins in a second direction crossing the first direction. A first dummy gate extends across the active fins and the first device isolation layer in the second direction. A second dummy gate extends across the second device isolation layer in the second direction.

A semiconductor structure includes a plurality of semiconductor fins located on a semiconductor substrate, in which each of the semiconductor fins comprises a sequential stack of a buffered layer including a III-V semiconductor material and a channel layer including a III-V semiconductor material. The semiconductor structure further includes a gap filler material surrounding the semiconductor fins and including a plurality of trenches therein. The released portions of the channel layers of the semiconductor fins located in the trenches constitute nanowire channels of the semiconductor structure, and opposing end portions of the channel layers of the semiconductor fins located outside of the trenches constitute a source region and a drain region of the semiconductor structure, respectively. In addition, the semiconductor structure further includes a plurality of gates structures located within the trenches that surround the nanowire channels in a gate all around configuration.

According to an embodiment of the present invention, self-aligned gate cap, comprises a gate located on a substrate; a gate cap surrounding a side of the gate; a contact region self-aligned to the gate; and a low dielectric constant oxide having a dielectric constant of less than 3.9 located on top of the gate. According to an embodiment of the present invention, a method of forming a self-aligned contact comprises removing at least a portion of an interlayer dielectric layer to expose a top surface of a gate cap located on a substrate; recessing the gate cap to form a recessed area; depositing a low dielectric constant oxide having a dielectric constant of less than 3.9 in the recessed area; and polishing a surface of the low dielectric constant oxide to expose a contact area.

A fin-type field effect transistor comprising a substrate, at least one gate structure, spacers and source and drain regions is described. The substrate has a plurality of fins and a plurality of insulators disposed between the fins. The source and drain regions are disposed on two opposite sides of the at least one gate structure. The gate structure is disposed over the plurality of fins and disposed on the plurality of insulators. The gate structure includes a stacked strip disposed on the substrate and a gate electrode stack disposed on the stacked strip. The spacers are disposed on opposite sidewalls of the gate structure, and the gate electrode stack contacts with sidewalls of the opposite spacers.

A fin-type field effect transistor device including a substrate, at least one gate stack structure, spacers and source and drain regions is described. The gate stack structure is disposed on the substrate and the spacers are disposed on sidewalls of the gate stack structure. The source and drain regions are disposed in the substrate and located at opposite sides of the gate stack structures. A dielectric layer having contact openings is disposed over the substrate and covers the gate stack structures. Metal connectors are disposed within the contact openings and connected to the source and drain regions, and adhesion layers are sandwiched between the contact openings and the metal connectors located within the contact openings.