A semiconductor fabrication apparatus comprises a process chamber, an ozone supply that provides the process chamber with ozone, an oxygen supply that provides the ozone supply with a source gas of the ozone, and a plurality of impurity detectors disposed between the oxygen supply and the ozone supply. The impurity detectors detect an inactive gas in the source gas.

Provided is a semiconductor device, including at least: a semiconductor layer; and a gate electrode that is arranged directly or via another layer on the semiconductor layer, the semiconductor device being configured in such a manner as to cause a current to flow in the semiconductor layer at least in a first direction that is along with an interface between the semiconductor layer and the gate electrode, the semiconductor layer having a corundum structure, a direction of an m-axis in the semiconductor layer being the first direction.

A semiconductor structure, a fabricating method thereof and a semiconductor device, the structure includes a substrate having a STI region and an AA, with an upper surface of the STI region lower than an upper surface of the AA; a stacked covered on the substrate; a first insulating layer covered the stacked structure, a second insulating layer covered the first insulating layer, and a third insulating layer covered the second insulating layer, over the STI region; a first insulating layer covered the stacked structure, over the AA, with an upper surface of the first insulating layer coplanar with an upper surface of the third insulating layer. The structure provides a semiconductor structure having a flat upper surface, avoiding polishing the first insulating layer over the AA to level with the first insulating layer over the STI region, greatly increasing the leakage risk, and reducing working stability of semiconductor devices.

There is provided a semiconductor film that includes an aggregate of semiconductor quantum dots that contain a Pb atom, and a ligand that is coordinated to the semiconductor quantum dot, in which a ratio of the number of Pb atoms having a valence of 1 or less to the number of Pb atoms having a valence of 2 is 0.20 or less. There are also provided a photodetector element, an image sensor, and a manufacturing method for a semiconductor film.

Provided is a semiconductor device including; at least a semiconductor layer; and a gate electrode that is arranged directly or via another layer on the semiconductor layer, the semiconductor device being configured in such a manner as to cause a current to flow in the semiconductor layer at least in a first direction that is along with an interface between the semiconductor layer and the gate electrode, the semiconductor layer having a corundum structure, a direction of a c-axis in the semiconductor layer being the first direction.

An integrated circuit device including a substrate including a word line trench and a first recess adjacent to a first side wall portion of an inner wall of the word line trench, a channel region on the inner wall and extending in a first direction parallel to an upper surface of the substrate, the channel region including a first channel region in a portion of the substrate adjacent to the inner wall and a second channel region on the inner wall and including a two-dimensional (2D) material of a first conductivity type, a gate insulating layer on the second channel region, a word line on the gate insulating layer and inside the word line trench, and a source region in a first recess and including the 2D material of the first conductivity type may be provided.

Methods for treating a thin film made from a conductive or semiconductive material may improve the crystalline quality thereof. Such methods may include: supplying a substrate including, on one of the faces thereof, a thin film of the material; and biased plasma treating the assembly formed by the substrate and the thin film at a given temperature and for a given time, so as to obtain a crystalline reorganization over a depth of the thin film, the biased plasma treatment including an electrical biasing of the thin film and an exposure of the film thus biased to a hydrogen plasma, the biased plasma treatment being implemented at a temperature that is below the melting points of the thin film and of the substrate.

A method for manufacturing a semiconductor film includes placing a semiconductor substrate including a β-Ga.sub.2O.sub.3-based single crystal in a reaction chamber of an HVPE apparatus. When the semiconductor substrate is placed so that the growth base surface faces upward, an inlet for a dopant-including gas into the space is positioned higher than an inlet for an oxygen-including gas into the space and an inlet for a Ga chloride gas into the space is positioned higher than the inlet for the dopant-including gas into the space. When the semiconductor substrate is placed so that the growth base surface faces downward, the inlet for the dopant-including gas into the space is positioned higher than the inlet for the Ga chloride gas into the space and the inlet for the oxygen-including gas into the space is positioned higher than the inlet for the dopant-including gas into the space.

A method for fabricating a semiconductor device includes the steps of: providing a substrate having a first region, a second region, and a third region; forming a first gate oxide layer on the first region, the second region, and the third region; and performing an etching process and an infrared treatment process at the same time to completely remove the first gate oxide layer on the second region for exposing the substrate.

According to one embodiment, a composition including a compound is provided. The compound includes a linking group containing 2 to 18 carbon atoms, a polymerizable functional group bonded to the linking group, a first reactive group bonded to the linking group, and a second reactive group bonded to the linking group. The polymerizable functional group includes at least one of a (meth)acryloyl group or a vinyl group. The first reactive group includes at least one selected from the group consisting of a thiol group, a disulfide group, and a thiocyanate group. The second reactive group includes at least one selected from the group consisting of an alkoxysilane group, a chlorosilane group, and a hydroxyl group.