A semiconductor device includes a semiconductor layer containing metal atoms, a charge storage layer provided on a surface of the semiconductor layer via a first insulating film, and an electrode layer provided on a surface of the charge storage layer via a second insulating film. The thickness of the first insulating film is 5 nm or more and 10 nm or less. The concentration of the metal atoms in the semiconductor layer is 5.010.sup.17 [EA/cm.sup.3] or higher and 1.310.sup.20 [EA/cm.sup.3] or lower.

A method and structure for providing uniform, large-area graphene by way of a transfer-free, direct-growth process. In some embodiments, a SAM is used as a carbon source for direct graphene synthesis on a substrate. For example, a SAM is formed on an insulating surface, and a metal layer is formed over the SAM. The metal layer may serve as a catalytic metal, whereby the SAM is converted to graphene following an annealing process. The SAM is deposited using a VPD process (e.g., an ALD process and/or an MLD process). In some embodiments, a CNT having a controlled diameter may be formed on the surface of a nanorod by appropriately tuning the geometry of the nanorod. Additionally, in some embodiments, a curved graphene transistor may be formed over a curved oxide surface, thereby providing a band gap in a channel region of the graphene transistor.

A method of preparing crystalline graphene includes performing a first thermal treatment including supplying heat to an inorganic substrate in a reactor, introducing a vapor carbon supply source into the reactor during the first thermal treatment to form activated carbon, and binding of the activated carbon on the inorganic substrate to grow the crystalline graphene.

A method of producing a reduced-defect density crystalline silicon film includes forming a first intrinsic silicon film on a substrate, forming a doped film including silicon or germanium on the first intrinsic silicon film, forming a second intrinsic silicon film on the doped film, and annealing to crystallize the doped film, the second intrinsic silicon film, and the first intrinsic silicon, wherein each film is amorphous at formation, wherein crystallization initiates within the doped film. A method of forming a thin film transistor includes forming an active layer in the crystallized second intrinsic silicon layer by doping the crystallized second intrinsic silicon layer in selected areas to form source and drain regions separated by a channel portion, forming a gate insulator layer on the crystallized second intrinsic silicon layer, and forming a gate electrode pattern over the gate insulator layer.

The present invention provides two methods for crystallizing a metal oxide semiconductor layer and a semiconductor structure. The first crystallization method is treating an amorphous metal oxide semiconductor layer including indium with oxygen at a pressure of about 550 mtorr to about 5000 mtorr and at a temperature of about 200 C. to about 750 C. The second crystallization method is, firstly, sequentially forming a first amorphous metal oxide semiconductor layer, an aluminum layer, and a second amorphous metal oxide semiconductor layer on a substrate, and, secondly, treating the first amorphous metal oxide semiconductor layer, the aluminum layer, and the second amorphous metal oxide semiconductor layer with an inert gas at a temperature of about 350 C. to about 650 C.

According to an embodiment, the substrate treatment device includes a dilutor configured to dilute a first liquid containing a metal ion and exhibiting acidity. The device further includes a pH changer configured to change a pH of the first liquid before or after being diluted by the dilutor. The device further includes a substrate conditioner configured to treat the substrate using the first liquid, which is diluted by the dilutor and with the pH changed by the pH changer.

A thin film transistor includes an active layer including a first portion having a first thickness and a second portion having a second thickness greater than the first thickness, a capping layer filling a thickness difference between the first portion and the second portion and arranged on the first portion, a gate insulating layer arranged on the capping layer, a gate electrode on the active layer, wherein the gate insulating layer and the capping layer are disposed between the gate electrode and the active layer, and a source electrode and a drain electrode connected to the active layer.

Embodiments of this disclosure provide a thin film of poly-silicon and a method for fabricating the same, and a thin film transistor and a method for fabricating the same, where a metal layer, a buffer layer, and an amorphous-silicon layer are formed on an underlying substrate successively, and metal atoms of the metal layer can be diffused to come into contact with the amorphous-silicon layer, so that the amorphous-silicon can be converted into a poly-silicon layer under the catalysis of the metal ions.

A semiconductor device production system using a laser crystallization method is provided which can avoid forming grain boundaries in a channel formation region of a TFT, thereby preventing grain boundaries from lowering the mobility of the TFT greatly, from lowering ON current, and from increasing OFF current. Rectangular or stripe pattern depression and projection portions are formed on an insulating film. A semiconductor film is formed on the insulating film. The semiconductor film is irradiated with continuous wave laser light by running the laser light along the stripe pattern depression and projection portions of the insulating film or along the major or minor axis direction of the rectangle. Although continuous wave laser light is most preferred among laser light, it is also possible to use pulse oscillation laser light in irradiating the semiconductor film.

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.