Provided is a method for forming a chalcogenide thin film, the method including forming a chalcogen element-containing film on a carrier substrate, disposing the chalcogen element-containing film on a silicon wafer, wherein the surface of the silicon wafer and the surface of the chalcogen element-containing film are in contact with each other, performing heat treatment on the silicon wafer and the chalcogen element-containing film at least one time, and removing the carrier substrate. The silicon wafer has a crystal plane of (111).

A single crystal semiconductor includes a strain compensation layer; an amorphous substrate disposed on the strain compensation layer; a lattice matching layer disposed on the amorphous substrate and including two or more single crystal layers; and a single crystal semiconductor layer disposed on the lattice matching layer, the lattice matching layer including a direction control film disposed on the amorphous substrate and including a single crystal structure, and a buffer layer including a material different from that of the direction control film, the buffer layer being disposed on the direction control film and including a single crystal structure.

A method of making a silicon on insulator structure comprises: providing a bonded structure, the bonded structure comprises the first substrate, the second substrate and the insulating buried layer, the insulating buried layer is positioned between the first substrate and the second substrate; peeling off a layer of removing region of the first substrate from the bonded structure to obtain a first film; at a first temperature, performing a first etching to etch the first film to remove a first thickness of the first film; at a second temperature, performing a second etching to etch the first film to planarize the first film and remove a second thickness of the first film, the first temperature being lower than the second temperature, the first thickness being greater than the second thickness, and a sum of the first thickness and the second thickness being a total etching thickness of the first film.

A composition, method, and system for directly printing and creating complete functional 3D electronic circuits and devices without any thermal or laser post-processing treatment, by using at least Triphenylamine (TPA) as a powder binding agent. The composition can have mechanical characteristics that allow it to be melted and extruded on a structure, and electrical properties that allow it to function as at least one of a conductor, insulator, resistor, p-type semiconductor, n-type semiconductor, or capacitor.

A semiconductor device include a substrate, a buffer layer formed on the substrate, a channel layer formed by an intrinsic polycrystalline silicon layer on the buffer layer, polycrystalline source and drain by non-intrinsic silicon formed on both sides of the polycrystalline silicon layer, a source electrode and a drain electrode formed on the polycrystalline source and the drain, a gate electrode corresponding to the channel layer, and an NiSi.sub.2 contact layer located between the source and the source electrode and between the drain and the drain electrode.

A method of manufacturing a semiconductor device includes steps of (i) forming a buffer layer of an insulating material on a substrate, (ii) forming a seed layer of catalyst material containing Ni on the buffer layer, (iii) forming, on the buffer layer, an amorphous intrinsic silicon layer for forming a channel, (iv) forming, on the amorphous intrinsic silicon layer, a non-intrinsic silicon layer for forming a source and/or drain, (v) forming a metal layer on the non-intrinsic silicon layer, and (vi) performing metal induced crystallization (MIC) process for crystallization of the amorphous intrinsic silicon layer and the amorphous non-intrinsic silicon layer, and activation of the amorphous non-intrinsic silicon layer to form a conductive area.

A method of manufacturing a polycrystalline silicon layer for a display device includes the steps of forming an amorphous silicon layer on a substrate, cleaning the amorphous silicon layer with hydrofluoric acid, rinsing the amorphous silicon layer with hydrogenated deionized water, and irradiating the amorphous silicon layer with a laser beam to form a polycrystalline silicon layer.

A composition, method, and system for directly printing and creating complete functional 3D electronic circuits and devices without any thermal or laser post-processing treatment, by using at least Triphenylamine (TPA) as a powder binding agent. The composition can have mechanical characteristics that allow it to be melted and extruded on a structure, and electrical properties that allow it to function as at least one of a conductor, insulator, resistor, p-type semiconductor, n-type semiconductor, or capacitor.

A semiconductor device with favorable electrical characteristics is provided. A semiconductor device with stable electrical characteristics is provided. A highly reliable display device is provided. The semiconductor device is fabricated by a method that includes a first step of forming a semiconductor layer containing a metal oxide, a second step of forming a conductive film over the semiconductor layer, a third step of etching the conductive film such that the conductive film is divided over the semiconductor layer and a portion of the semiconductor layer is uncovered, and a fourth step of performing first treatment on the conductive film and the portion of the semiconductor layer. The conductive film contains copper, silver, gold, or aluminum. The first treatment is plasma treatment in an atmosphere containing a mixed gas of a first gas containing an oxygen element and a second gas containing a hydrogen element.

A method of forming graphene on a flexible substrate includes providing a polymer substrate including a metal structure and providing a carbon source and a carrier gas. The method also includes subjecting the polymer substrate to a plasma enhanced chemical vapor deposition (PECVD) process and growing a graphene layer on the copper structure.