Abstract: Methods of fabricating a fin field effect transistor (FinFET) are disclosed. Embodiments of the invention provide methods of fabricating FinFETs by optimizing a method for forming the fin so that a short channel effect is prevented and high integration is achieved. Accordingly, the fin which has a difficulty in its formation using the current photolithography-etching technique may be readily formed.

Abstract: According to some embodiments of the invention, transistors of a semiconductor device have a punchthrough protection layer, and methods of forming the same are provided. A channel-portion hole extends downward from a main surface of a semiconductor substrate. A punchthrough protection layer and a channel-portion layer are sequentially formed at a lower portion of the channel-portion hole. A word line pattern fills an upper portion of the channel-portion hole, and is formed on the semiconductor substrate. The word line pattern is formed to have a word line and a word line capping layer pattern stacked thereon, and the channel-portion layer is a channel region. The punchthrough protection layer can reduce a leakage current of a capacitor of the transistor embodied in a DRAM.

Abstract: The method of manufacturing a recess type MOS transistor improves a refresh characteristic. In the method, a channel impurity region is formed by ion implanting a first conductive impurity in an active region of a semiconductor substrate. Thereon, a second conductive impurity and the first conductive impurity are ion-implanted each alternately into the active region, to thus sequentially form first to third impurity regions having a dual diode structure on the channel impurity region, the second conductive impurity having conductivity opposite to the first conductive impurity. A trench is formed, and a gate insulation layer is formed in a gate region to produce a gate stack. The first conductive impurity is selectively ion-implanted in a source region, to thus form a fourth impurity region. A spacer is then formed in a sidewall of the gate stack, and the second conductive impurity is ion-implanted in the source/drain regions, to form a fifth impurity region.

Abstract: According to some embodiments of the invention, transistors of a semiconductor device have a channel region in a channel-portion hole. Methods include forming embodiments of the transistor having a channel-portion hole disposed in a semiconductor substrate. A channel-portion trench pad and a channel-portion layer are sequentially formed at a lower portion of the channel-portion hole. A word line insulating layer pattern and a word line pattern are sequentially stacked on the channel-portion layer and fill the channel-portion hole, disposed on the semiconductor substrate. The channel-portion layer is formed to contact the semiconductor substrate through a portion of sidewall of the channel-portion hole, and forms a channel region under the word line pattern. Punchthrough is prevented between electrode impurity regions corresponding to source and drain regions.

Abstract: According to some embodiments of the invention, a method includes preparing a semiconductor substrate having an active region, doping channel ions in the active region, forming a planarized selective epitaxial growth (SEG) layer in a predetermined region of the active region doped with the channel ions, sequentially forming a gate insulating layer, a gate conductive layer and a gate hard mask layer on the semiconductor substrate having the planarized SEG layer, forming a gate pattern crossing the active region by sequentially patterning the gate hard mask layer and the gate conductive layer, the planarized SEG layer being located at one side of the gate pattern, and forming source/drain regions by implanting impurity ions using the gate pattern as an ion implantation mask. Accordingly, there is provided an asymmetric source/drain transistor capable of preventing a leakage current by diffusing the channel ions into the SEG layer.

Abstract: A finFET device includes a semiconductor substrate having specific regions surrounded with a trench. The trench is filled with an insulating layer, and recess holes are formed within the specific regions such that channel fins are formed by raised portions of the semiconductor substrate on both sides of the recess holes. Gate lines are formed to overlie and extend across the channel fins. Source/drain regions are formed at both ends of the channel fins and connected by the channel fins. Other embodiments are described and claimed.

Abstract: For fabricating a field effect transistor, an extra-doped channel region is formed below a surface of a semiconductor substrate. An opening is formed in the semiconductor substrate into the extra-doped channel region. A gate insulator is formed at walls of the opening such that the extra-doped channel region abuts the gate insulator at a bottom portion of the opening. The opening is filled with a gate electrode. Such an extra-doped channel region prevents undesired body effect in the field effect transistor.

Abstract: A semiconductor memory device and fabrication method of same includes the processes of forming sacrifice gates on a silicon substrate with the sacrifice gates apart from each other. A first conductive layer is formed on an exposed portion of the silicon substrate between the sacrifice gates and a first inter-insulation layer is formed that exposes the first conductive layer and the sacrifice gates. The exposed sacrifice gates are removed to form openings and damascene gates are subsequently formed in the openings. Capping layers are formed on the top of the gates and a second conductive layer is formed on the exposed first conductive layer. A second inter-insulation layer is formed on the silicon substrate, and bit line contacts that expose the second conductive layer are formed by etching the second inter-insulation layer.

Abstract: a A MOS (metal oxide semiconductor) transistor with a trench-type gate is fabricated with a channel stopping region for forming an asymmetric channel region for reducing short channel effects. For example in fabricating an N-channel MOS transistor, a gate structure is formed within a trench that is within a P-well. A channel stopping region with a P-type dopant is formed to a first side of the trench to completely contain an N-type source junction therein. An N-type drain junction is formed within a LDD region to a second side of the trench, thus forming the asymmetric channel region.

Abstract: A semiconductor memory device includes a silicon substrate with a gate and contact pads at both sides of the gate, an inter-insulation layer formed on the substrate, including a storage node contact and a bit-line contact exposing a corresponding contact pad, and including a groove-shaped bit-line pattern, a storage node contact plug formed in the storage node contact, and a damascene bit line formed within the bit-line pattern and connected with the exposed corresponding contact pad through the bit-line contact.

Abstract: A semiconductor memory device and fabrication method of same includes the processes of forming sacrifice gates on a silicon substrate with the sacrifice gates apart from each other. A first conductive layer is formed on an exposed portion of the silicon substrate between the sacrifice gates and a first inter-insulation layer is formed that exposes the first conductive layer and the sacrifice gates. The exposed sacrifice gates are removed to form openings and damascene gates are subsequently formed in the openings. Capping layers are formed on the top of the gates and a second conductive layer is formed on the exposed first conductive layer. A second inter-insulation layer is formed on the silicon substrate, and bit line contacts that expose the second conductive layer are formed by etching the second inter-insulation layer.

Abstract: Disclosed is an apparatus for increasing rotation force using a magnetic force capable of generating the electric power by increasing an initial driving force using permanent magnets opposed to each other and driving an electric generator using the increased turning force. The apparatus comprises a turning force increasing means including a rotary driving member receiving a power via a shaft thereof; and a rotary driven member disposed on the rotary driving and rotated by a magnetic force of the rotary driving member. Each of the rotary driving member and the rotary driven member includes a pair of covers at both ends thereof, and a plurality of magnets disposed between the covers along a periphery.

Abstract: Unit cells of a static random access memory (SRAM) are provided including an integrated circuit substrate and first and second active regions. The first active region is provided on the integrated circuit substrate and has a first portion and a second portion. The second portion is shorter than the first portion. The first portion has a first end and a second end and the second portion extends out from the first end of the first portion. The second active region is provided on the integrated circuit substrate. The second active region has a third portion and a fourth portion. The fourth portion is shorter than the third portion. The third portion is remote from the first portion of the first active region and has a first end and a second end. The fourth portion extends out from the second end of the third portion towards the first portion of the first active region and is remote from the second portion of the first active region. Methods of forming SRAM cells are also described.

Abstract: A semiconductor memory device includes a silicon substrate with a gate and contact pads at both sides of the gate, an inter-insulation layer formed on the substrate, including a storage node contact and a bit-line contact exposing a corresponding contact pad, and including a groove-shaped bit-line pattern, a storage node contact plug formed in the storage node contact, and a damascene bit line formed within the bit-line pattern and connected with the exposed corresponding contact pad through the bit-line contact.

Abstract: A semiconductor memory device and fabrication method of same includes the processes of forming sacrifice gates on a silicon substrate with the sacrifice gates apart from each other. A first conductive layer is formed on an exposed portion of the silicon substrate between the sacrifice gates and a first inter-insulation layer is formed that exposes the first conductive layer and the sacrifice gates. The exposed sacrifice gates are removed to form openings and damascene gates are subsequently formed in the openings. Capping layers are formed on the top of the gates and a second conductive layer is formed on the exposed first conductive layer. A second inter-insulation layer is formed on the silicon substrate, and bit line contacts that expose the second conductive layer are formed by etching the second inter-insulation layer.

Abstract: A modeling method of a steering system for a vehicle comprises the steps of interpreting a coupled relation between an upper tube and a lower tube comprising a steering column, interpreting a coupled relation between the upper tube and an upper bracket and a coupled relation between the lower tube and a lower bracket, and interpreting the movement of a bearing mounted between a steering axle and a steering column using a cylindrical coordinate, thereby improving credibility relative to the interpretation result of a model When the interpretation result is applied to an actual vehicle, the impact absorption capacity and idle vibration capacity are greatly increased, thereby improving the performance of the overall steering system and ensuring safety to the occupants of the vehicle.

Abstract: In a method of fabricating a semiconductor device having a gate all around(GAA) structure transistor, an SOI substrate having a SOI layer, a buried oxide layer, and a bottom substrate is prepared. The SOI layer is patterned to form an active layer pattern. An etch stopping layer having an etch selectivity with respect to the buried oxide layer and the active layer pattern is stacked on the active layer pattern. The etch stopping layer pattern is patterned and removed at the gate region crossing the active layer pattern at the channel region, to form an etch stopping layer pattern and to expose the buried oxide layer. The buried oxide layer is isotropically etched using the etch stopping layer pattern as an etch mask to form a cavity at the channel region bottom of the active layer pattern. A conductive material fills the cavity and a space between the etch stopping layer pattern at the gate region. In this manner, the number of photolithography processes required for forming the device is reduced.

Abstract: In a method of fabricating a semiconductor device having a gate all around (GAA) structure transistor, an SOI substrate having a SOI layer, a buried oxide layer, and a bottom substrate is prepared. The SOI layer is patterned to form an active layer pattern. An etch stopping layer having an etch selectivity with respect to the buried oxide layer and the active layer pattern is stacked on the active layer pattern. The etch stopping layer pattern is patterned and removed at the gate region crossing the active layer pattern at the channel region, to form an etch stopping layer pattern and to expose the buried oxide layer. The buried oxide layer is isotropically etched using the etch stopping layer pattern as an etch mask to form a cavity at the channel region bottom of the active layer pattern. A conductive material fills the cavity and a space between the etch stopping layer pattern at the gate region. In this manner, the number of photolithography processes required for forming the device is reduced.

Abstract: Method for forming an oxide film in a semiconductor device, is disclosed, which is suitable to form oxide films of different thicknesses in a device region, to which driving voltages of different levels are applied respectively, including the steps of providing a semiconductor substrate, forming an insulating film on the semiconductor substrate, injecting first, and second impurity ions into the semiconductor substrate through the exposed insulating film after masking required regions of the insulating film, removing the insulating film, and forming first, and second oxide films having thicknesses different from each other on regions of the semiconductor substrate having the impurity ions are injected and the impurity ions are not injected thereto, respectively.

Abstract: A fabrication method for a semiconductor memory device includes the steps of forming a gate pattern on a semiconductor substrate; forming first and second sidewall spacers at sides of the gate pattern; performing an ion=implantation of a high concentration impurity using the gate pattern and the first and second sidewall spacers as a mask, thereby forming an impurity diffusion region in the semiconductor substrate; performing an ion-implantation of a transition metal on the semiconductor substrate including the gate pattern and the first and second sidewall spacers, and then forming a polysilicide and a silicide by annealing; and removing the second sidewall spacers.