The reliability of a transistor including an oxide semiconductor is improved. The transistor in a semiconductor device includes a first oxide semiconductor film over a first insulating film, a gate insulating film over the first oxide semiconductor film, a second oxide semiconductor film over the gate insulating film, and a second insulating film over the first oxide semiconductor film and the second oxide semiconductor film. The first oxide semiconductor film includes a channel region overlapping with the second oxide semiconductor film, a source region and a drain region each in contact with the second insulating film. The channel region includes a first layer and a second layer in contact with a top surface of the first layer and covering a side surface of the first layer in the channel width direction. The second oxide semiconductor film has a higher carrier density than the first oxide semiconductor film.

Embodiments are directed to forming a structure comprising at least one fin, a gate, and a spacer, applying an annealing process to the structure to create a gap between the at least one fin and the spacer, and growing an epitaxial semiconductor layer in the gap between the spacer and the at least one fin.

Method of making a transistor with semiconducting nanowires, including: making a semiconducting nanowire on a support, one portion of the nanowire being covered by a dummy gate, in which the dummy gate and the nanowire are surrounded by a dielectric layer, removing the dummy gate, forming a first space surrounded by first parts of the dielectric layer, making an ion implantation in a second part of the dielectric layer under said first portion, said first parts protecting third parts of the dielectric layer, etching said second part, forming a second space, making a gate in the spaces, and a dielectric portion on the gate and said first parts, making an ion implantation in fourth parts of the dielectric layer surrounding second portions of the nanowire, the dielectric portion protecting said first and third parts, etch said fourth parts.

A semiconductor device includes a gate positioned on a substrate; a nanosheet that extends through the gate, protrudes from a sidewall of the gate, and forms a recess between the substrate and the nanosheet; a dielectric spacer disposed in the recess; a source/drain contact positioned on a source/drain disposed on the substrate adjacent to the gate; an air gap spacer positioned along the sidewall of the gate and in contact with a dielectric material disposed on the nanosheet, the air gap spacer being in contact with the source/drain contact; and an interlayer dielectric (ILD) disposed on the air gap spacer.

A transistor with stable electrical characteristics is provided. Provided is a method for manufacturing a semiconductor device that includes, over a substrate, an oxide semiconductor, a first conductor, a first insulator, a second insulator, and a third insulator. The oxide semiconductor is over the first insulator. The second insulator is over the oxide semiconductor. The third insulator is over the second insulator. The first conductor is over the third insulator. The oxide semiconductor has a first region and a second region. To form the first region, ion implantation into the oxide semiconductor is performed using the first conductor as a mask, and then hydrogen is added to the oxide semiconductor using the first conductor as a mask.

An object is to improve field effect mobility of a thin film transistor using an oxide semiconductor. Another object is to suppress increase in off current even in a thin film transistor with improved field effect mobility. In a thin film transistor using an oxide semiconductor layer, by forming a semiconductor layer having higher electrical conductivity and a smaller thickness than the oxide semiconductor layer between the oxide semiconductor layer and a gate insulating layer, field effect mobility of the thin film transistor can be improved, and increase in off current can be suppressed.

A semiconductor device for high power application in which a novel semiconductor material having high mass productivity is provided. An oxide semiconductor film is formed, and then, first heat treatment is performed on the exposed oxide semiconductor film in order to reduce impurities such as moisture or hydrogen in the oxide semiconductor film. Next, in order to further reduce impurities such as moisture or hydrogen in the oxide semiconductor film, oxygen is added to the oxide semiconductor film by an ion implantation method, an ion doping method, or the like, and after that, second heat treatment is performed on the exposed oxide semiconductor film.

The present invention provides a field effect transistor and the method for preparing such a filed effect transistor. The filed effect transistor comprises a semiconductor, germanium nanowires, a first III-V compound layer surrounding the germanium nanowires, a semiconductor barrier layer, a gate dielectric layer and a gate electrode sequentially formed surrounding the first III-V compound layer, and source/drain electrodes are respectively located at each side of the gate electrode and on the first III-V compound layer. According to the present invention, the band width of the barrier layer is greater than that of the first III-V compound layer, and the band curvatures of the barrier layer and the first III-V compound layer are different, therefore, a two-dimensional electron gas (2DEG) is formed in the first III-V compound layer near the barrier layer boundary. Since the 2DEG has higher mobility, the performance of the filed effect transistor improved. Besides, the performance of the filed effect transistor also improved due to the structure is a gate-all-around structure.

Semiconductor devices are fabricated with vertical field effect transistor (FET) devices having uniform structural profiles. Semiconductor fabrication methods for vertical FET devices implement a process flow to fabricate dummy fins within isolation regions to enable the formation of vertical FET devices with uniform structural profiles within device regions. Sacrificial semiconductor fins are formed in the isolation regions concurrently with semiconductor fins in the device regions, to minimize/eliminate micro-loading effects from an etch process used for fin patterning and, thereby, form uniform profile semiconductor fins. The sacrificial semiconductor fins within the isolation regions also serve to minimize/eliminate non-uniform topography and micro-loading effects when planarizing and recessing conductive gate layers and, thereby form conductive gate structures for vertical FET devices with uniform gate lengths in the device regions. The sacrificial semiconductor fins are subsequently removed and replaced with insulating material to form the dummy fins.

A method for integrating vertical transistors and electric fuses includes forming fins through a dielectric layer and a dummy gate stack on a substrate; thinning top portions of the fins by an etch process; epitaxially growing top source/drain regions on thinned portions of the fins in a transistor region and top cathode/anode regions on the thinned portions of the fins in a fuse region; and removing the dummy gate layer and exposing sidewalls of the fins. The fuse region is blocked to form a gate structure in the transistor region. The transistor region is blocked and the fuse region is exposed to conformally deposit a metal on exposed sidewalls of the fins. The metal is annealed to form silicided fins. Portions of the substrate are separated to form bottom source/drain regions for vertical transistors in the transistor region and bottom cathode/anode regions for fuses in the fuse region.