Abstract: A method of manufacturing a bottom gate thin film transistor (“TFT”) in which a polycrystalline channel region having a large grain size is formed relatively simply and easily. The method of manufacturing a bottom gate thin film transistor includes forming a bottom gate electrode on a substrate, forming a gate insulating layer on the substrate to cover the bottom gate electrode, forming an amorphous semiconductor layer, an N-type semiconductor layer and an electrode layer on the gate insulating layer sequentially, etching an electrode region and an N-type semiconductor layer region formed on the bottom gate electrode sequentially to expose an amorphous semiconductor layer region, melting the amorphous semiconductor layer region using a laser annealing method, and crystallizing the melted amorphous semiconductor layer region to form a laterally grown polycrystalline channel region.

Abstract: A microlens, an image sensor including the microlens, a method of forming the microlens and a method of manufacturing the image sensor are provided. The microlens includes a polysilicon pattern, having a cylindrical shape, formed on a substrate, and a round-type shell portion enclosing the polysilicon pattern. The microlens may further include a filler material filling an interior of the shell portion, or a second shell portion covering the first shell portion. The method of forming a microlens includes forming a silicon pattern on a semiconductor substrate having a lower structure, forming a capping film on the semiconductor substrate over the silicon pattern, annealing the silicon pattern and the capping film altering the silicon pattern to a polysilicon pattern having a cylindrical shape and the capping film to a shell portion for a round-type microlens, and filling an interior of the shell portion with a lens material through an opening between the semiconductor substrate and an edge of the shell portion.

Abstract: A microlens, an image sensor including the microlens, a method of forming the microlens and a method of manufacturing the image sensor are provided. The microlens includes a polysilicon pattern, having a cylindrical shape, formed on a substrate, and a round-type shell portion enclosing the polysilicon pattern. The microlens may further include a filler material filling an interior of the shell portion, or a second shell portion covering the first shell portion. The method of forming a microlens includes forming a silicon pattern on a semiconductor substrate having a lower structure, forming a capping film on the semiconductor substrate over the silicon pattern, annealing the silicon pattern and the capping film altering the silicon pattern to a polysilicon pattern having a cylindrical shape and the capping film to a shell portion for a round-type microlens, and filling an interior of the shell portion with a lens material through an opening between the semiconductor substrate and an edge of the shell portion.

Abstract: A transistor includes; at least two polycrystalline silicon layers disposed substantially parallel to each other, each polycrystalline silicon layer including a channel region and at least two high conductivity regions disposed at opposing sides of the channel region; a gate which corresponds to the channel region of the two polycrystalline silicon layers and which crosses the two polycrystalline silicon layers, and a gate insulating layer interposed between the gate and the two polycrystalline silicon layers, wherein low conductivity regions are disposed adjacent to one edge of the gate and are formed between the channel region and one high conductivity region of each polycrystalline silicon layer.

Abstract: A microlens, an image sensor including the microlens, a method of forming the microlens and a method of manufacturing the image sensor are provided. The microlens includes a polysilicon pattern, having a cylindrical shape, formed on a substrate, and a round-type shell portion enclosing the polysilicon pattern. The microlens may further include a filler material filling an interior of the shell portion, or a second shell portion covering the first shell portion. The method of forming a microlens includes forming a silicon pattern on a semiconductor substrate having a lower structure, forming a capping film on the semiconductor substrate over the silicon pattern, annealing the silicon pattern and the capping film altering the silicon pattern to a polysilicon pattern having a cylindrical shape and the capping film to a shell portion for a round-type microlens, and filling an interior of the shell portion with a lens material through an opening between the semiconductor substrate and an edge of the shell portion.

Abstract: A transistor includes; at least two polycrystalline silicon layers disposed substantially parallel to each other, each polycrystalline silicon layer including a channel region and at least two high conductivity regions disposed at opposing sides of the channel region; a gate which corresponds to the channel region of the two polycrystalline silicon layers and which crosses the two polycrystalline silicon layers, and a gate insulating layer interposed between the gate and the two polycrystalline silicon layers, wherein low conductivity regions are disposed adjacent to one edge of the gate and are formed between the channel region and one high conductivity region of each polycrystalline silicon layer.

Abstract: A method of manufacturing a bottom gate thin film transistor (“TFT”) in which a polycrystalline channel region having a large grain size is formed relatively simply and easily. The method of manufacturing a bottom gate thin film transistor includes forming a bottom gate electrode on a substrate, forming a gate insulating layer on the substrate to cover the bottom gate electrode, forming an amorphous semiconductor layer, an N-type semiconductor layer and an electrode layer on the gate insulating layer sequentially, etching an electrode region and an N-type semiconductor layer region formed on the bottom gate electrode sequentially to expose an amorphous semiconductor layer region, melting the amorphous semiconductor layer region using a laser annealing method, and crystallizing the melted amorphous semiconductor layer region to form a laterally grown polycrystalline channel region.

Abstract: Provided are methods of forming a more highly-oriented silicon thin layer having a larger grain size, and a substrate having the same. The methods may include forming an aluminum (Al) layer on a base substrate, forming a more highly-oriented Al layer by recrystallizing the Al layer under vacuum, forming a more highly-oriented ?-Al2O3 layer on the more highly-oriented Al layer and/or epitaxially growing a silicon layer on the more highly-oriented ?-Al2O3 layer. The method may be used to manufacture a semiconductor device having higher carrier mobility.

Abstract: A thin film transistor (TFT) that can prevent damage to a silicon layer under a gate electrode in an annealing process by using a first gate electrode having high thermal resistance and a second gate electrode having high reflectance and a method of manufacturing the TFT are provided. The method of manufacturing a TFT includes forming a double-layered gate electrode which includes a first gate electrode formed of a material having high thermal resistance and a second gate electrode formed of a metal having high optical reflectance on the first gate electrode, and forming a source and a drain by annealing doped regions on both sides of a silicon layer under the gate electrode by radiating a laser beam onto the entire upper surface of the silicon layer.

Abstract: A method of manufacturing a bottom gate thin film transistor (“TFT”) in which a polycrystalline channel region having a large grain size is formed relatively simply and easily. The method of manufacturing a bottom gate thin film transistor includes forming a bottom gate electrode on a substrate, forming a gate insulating layer on the substrate to cover the bottom gate electrode, forming an amorphous semiconductor layer, an N-type semiconductor layer and an electrode layer on the gate insulating layer sequentially, etching an electrode region and an N-type semiconductor layer region formed on the bottom gate electrode sequentially to expose an amorphous semiconductor layer region, melting the amorphous semiconductor layer region using a laser annealing method, and crystallizing the melted amorphous semiconductor layer region to form a laterally grown polycrystalline channel region.

Abstract: Provided are a thin film transistor (TFT) including a selectively crystallized channel layer, and a method of manufacturing the TFT. The TFT includes a gate, the channel layer, a source, and a drain. The channel layer is formed of an oxide semiconductor, and at least a portion of the channel layer contacting the source and the drain is crystallized. In the method of manufacturing the TFT, the channel layer is formed of an oxide semiconductor, and a metal component is injected into the channel layer so as to crystallize at least a portion of the channel layer contacting the source and the drain. The metal component can be injected into the channel layer by depositing and heat-treating a metal layer or by ion-implantation.

Abstract: Provided are methods of forming nano crystals and method of manufacturing a memory device suing the same. In an example embodiment, a method of forming nano crystals may include forming an amorphous film on a substrate and converting the amorphous film into an oxide film having the nano crystals by annealing the amorphous film under oxidizing conditions under which part of the crystallized film is oxidized.

Abstract: A method of fabricating a single crystal silicon rod may include forming an insulation layer on a substrate, forming a hole in the insulation layer, selectively growing silicon in the hole, forming a silicon layer on the hole and on the insulation layer, forming a rod pattern on the silicon layer in a direction that is non-radial with respect to the hole, and melting the silicon layer and crystallizing the silicon layer by illuminating a laser beam on the silicon layer where the rod pattern is formed to generate a nucleation site at a position corresponding to the hole. According to the method, a single crystal silicon rod having no defects may be formed.

Abstract: A thin film transistor used as a selection transistor for a three-dimensional stacking cross point memory and a method of manufacturing the thin film transistor are provided. The thin film transistor includes a substrate, a gate, a gate insulation layer, a channel, a source and a drain. The gate may be formed on a portion of the substrate. The gate insulation layer may be formed on the substrate and the gate. The channel includes ZnO and may be formed on the gate insulation layer over the gate. The source and the drain contact sides of the channel.

Abstract: A microlens, an image sensor including the microlens, a method of forming the microlens and a method of manufacturing the image sensor are provided. The microlens includes a polysilicon pattern, having a cylindrical shape, formed on a substrate, and a round-type shell portion enclosing the polysilicon pattern. The microlens may further include a filler material filling an interior of the shell portion, or a second shell portion covering the first shell portion. The method of forming a microlens includes forming a silicon pattern on a semiconductor substrate having a lower structure, forming a capping film on the semiconductor substrate over the silicon pattern, annealing the silicon pattern and the capping film altering the silicon pattern to a polysilicon pattern having a cylindrical shape and the capping film to a shell portion for a round-type microlens, and filling an interior of the shell portion with a lens material through an opening between the semiconductor substrate and an edge of the shell portion.

Abstract: A method of manufacturing a bottom gate thin film transistor (“TFT”), in which a polycrystalline channel region having a large grain size is formed relatively simply and easily, includes forming a bottom gate electrode on a substrate, forming a gate insulating layer on the substrate to cover the gate electrode, forming an amorphous semiconductor layer on the gate insulating layer, patterning the amorphous semiconductor layer to form an amorphous channel region on the gate electrode, melting the amorphous channel region using a laser annealing method to form a melted amorphous channel region, and crystallizing the melted amorphous channel region to form a laterally grown polycrystalline channel region.

Abstract: A method of manufacturing a bottom gate thin film transistor (“TFT”) in which a polycrystalline channel region having a large grain size is formed relatively simply and easily. The method of manufacturing a bottom gate thin film transistor includes forming a bottom gate electrode on a substrate, forming a gate insulating layer on the substrate to cover the bottom gate electrode, forming an amorphous semiconductor layer, an N-type semiconductor layer and an electrode layer on the gate insulating layer sequentially, etching an electrode region and an N-type semiconductor layer region formed on the bottom gate electrode sequentially to expose an amorphous semiconductor layer region, melting the amorphous semiconductor layer region using a laser annealing method, and crystallizing the melted amorphous semiconductor layer region to form a laterally grown polycrystalline channel region.

Abstract: A transistor includes; at least two polycrystalline silicon layers disposed substantially parallel to each other, each polycrystalline silicon layer including a channel region and at least two high conductivity regions disposed at opposing sides of the channel region; a gate which corresponds to the channel region of the two polycrystalline silicon layers and which crosses the two polycrystalline silicon layers, and a gate insulating layer interposed between the gate and the two polycrystalline silicon layers, wherein low conductivity regions are disposed adjacent to one edge of the gate and are formed between the channel region and one high conductivity region of each polycrystalline silicon layer.

Abstract: Disclosed herein are methods of fabricating a polycrystalline silicon film and methods of fabricating a thin film transistor (TFT) using the same. The method of fabricating a polycrystalline silicon film includes forming an electrically insulating thermally conductive layer using a material selected from the group consisting of aluminum-containing ceramics, cobalt-containing ceramics, and iron-containing ceramics, on a substrate; forming an amorphous silicon layer on the thermally conductive layer; forming an amorphous silicon island by patterning the amorphous silicon layer; and crystallizing amorphous silicon by annealing the amorphous silicon island. A polycrystalline silicon film having a very large grain size and a TFT using the same can be formed in desired positions.

Abstract: Provided are methods of forming a more highly-oriented silicon thin layer having a larger grain size, and a substrate having the same. The methods may include forming an aluminum (Al) layer on a base substrate, forming a more highly-oriented Al layer by recrystallizing the Al layer under vacuum, forming a more highly-oriented ?-Al2O3 layer on the more highly-oriented Al layer and/or epitaxially growing a silicon layer on the more highly-oriented ?-Al2O3 layer. The method may be used to manufacture a semiconductor device having higher carrier mobility.