Disclosed are a method and a device for manufacturing an array substrate, and an array substrate. The method includes: depositing and forming a gate insulation layer on a pre-formed base substrate and a pre-formed gate, the gate insulation layer covering the pre-formed gate; depositing and forming an amorphous silicon layer, a doped amorphous silicon layer including at least three doped layers, and a metal layer on the gate insulation layer in sequence, doping concentrations of the at least three doped layers of the doped amorphous silicon layer increasing from bottom to top; etching patterns of the amorphous silicon layer, the doped amorphous silicon layer and the metal layer to form the array substrate.

A method of manufacturing, with high mass productivity, liquid crystal display devices having highly reliable thin film transistors with excellent electric characteristics is provided. In a liquid crystal display device having an inverted staggered thin film transistor, the inverted staggered thin film transistor is formed as follows: a gate insulating film is formed over a gate electrode; a microcrystalline semiconductor film which functions as a channel formation region is formed over the gate insulating film; a buffer layer is formed over the microcrystalline semiconductor film; a pair of source and drain regions are formed over the buffer layer; and a pair of source and drain electrodes are formed in contact with the source and drain regions so as to expose a part of the source and drain regions.

A transistor device and method of making the same, the transistor device including: a substrate; a word line disposed on the substrate; a gate insulating layer disposed on the word line; a dual-layer semiconductor channel including: a first channel layer disposed on the gate insulating layer; and a second channel layer disposed on the first channel layer, such that the second channel layer contacts side and top surfaces of the first channel layer; and source and drain electrodes electrically coupled to the second channel layer. When a voltage is applied to the word line, the first channel layer has a first electrical resistance and the second channel layer has a second electrical resistance that is different from the first electrical resistance.

An electronic device including a first substrate, a semiconductor layer, a second substrate and a color filter is disclosed. The first substrate has a peripheral region. The semiconductor layer is disposed on the first substrate in the peripheral region. The second substrate is opposite to the first substrate. The color filter is disposed between the first substrate and the second substrate and in the peripheral region of the first substrate, and the color filter overlaps the semiconductor layer.

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.

Provided are a semiconductor device and method of forming the same. The semiconductor device includes active components and a first barrier pattern. The active components are on a substrate. Each of the active components includes base insulation patterns on the substrate, gate electrodes on the substrate and spaced apart from each other with the base insulation patterns interposed therebetween, a gate dielectric layer on the gate electrodes and the base insulation patterns, a channel pattern on the gate dielectric layer, source electrodes on the channel pattern and spaced apart from each other, a drain electrode on the channel pattern and between the source electrodes, and second insulation patterns between the source electrodes and the drain electrode. The first barrier pattern disposed on the gate dielectric layer surrounds the channel patterns, the source electrodes, the drain electrodes, and the second insulation patterns of each of the active components.

A thin film transistor is provided. The thin film transistor includes abase substrate; a gate electrode on the base substrate; an active layer on the base substrate, the active layer including a polycrystalline silicon part including a polycrystalline silicon material and an amorphous silicon part including an amorphous silicon material; a gate insulating layer insulating the gate electrode from the active layer; a source electrode and a drain electrode on the base substrate; and an etch stop layer on a side of the polycrystalline silicon part away from the base substrate. An orthographic projection of the etch stop layer on the base substrate covers an orthographic projection of the polycrystalline silicon part on the base substrate, and an orthographic projection of at least a portion of the amorphous silicon part on the base substrate.

A semiconductor device, includes an insulating film formed on a substrate; a conductive layer, comprising first and second doped poly-silicon regions and a undoped poly-Si region, formed on the insulating film; a highly doped first conductivity type drain region and a highly doped a first conductivity type source region formed in the first and second doped poly-silicon regions, respectively; and a highly doped second conductivity type gate region formed in the undoped poly-Si region between the highly doped first conductivity type drain region and the highly doped first conductivity type source region. The undoped poly-Si region is disposed closer to the highly doped first conductivity type source region than the highly doped first conductivity type drain region.

Disclosed transistor structures include a gate electrode, an active layer, a gate dielectric layer separating the active layer from the gate electrode, a source electrode, a drain electrode, and a hydrogen-rich material layer separating the source electrode and the drain electrode from the active layer. The presence of hydrogen in the hydrogen-rich material layer may act to reduce contact resistances and Schottky barriers between the source electrode and the active layer, and between the drain electrode and the active layer, thus leading to improved device performance. The disclosed transistor structures may be formed in a BEOL process and may be incorporated with other BEOL circuit components. As such, the disclosed transistor structures may include materials that may be processed at low temperatures and thus, may not damage previously fabricated devices.

Provided are a semiconductor device and method of forming the same. The semiconductor device includes active components and a first barrier pattern. The active components are on a substrate. Each of the active components includes base insulation patterns on the substrate, gate electrodes on the substrate and spaced apart from each other with the base insulation patterns interposed therebetween, a gate dielectric layer on the gate electrodes and the base insulation patterns, a channel pattern on the gate dielectric layer, source electrodes on the channel pattern and spaced apart from each other, a drain electrode on the channel pattern and between the source electrodes, and second insulation patterns between the source electrodes and the drain electrode. The first barrier pattern disposed on the gate dielectric layer surrounds the channel patterns, the source electrodes, the drain electrodes, and the second insulation patterns of each of the active components.