Abstract: Provided is a method of fabricating a semiconductor device having a contact hole with a high aspect-ratio. The method includes: sequentially forming a lower pattern and an upper layer on a semiconductor substrate; sequentially forming a lower mask layer and an upper mask layer on the upper layer; sequentially patterning the lower and upper mask layers to form a hole exposing a top surface of the upper layer on the lower pattern; using the upper mask layer as an etching mask to anisotropically etch the exposed top surface to form an upper contact hole exposing a top surface of the lower pattern; and using the lower mask layer as an etching mask to anisotropically etch the exposed lower pattern to form a lower contact hole in the lower pattern, the lower contact hole extending from the upper contact hole.

Abstract: A method of fabricating a semiconductor device including a fin field effect transistor (Fin-FET) includes forming sacrificial bars on a semiconductor substrate, patterning the sacrificial bars to form sacrificial islands on the semiconductor substrate, forming a device isolation layer to fill a space between the sacrificial islands, selectively removing the sacrificial islands to expose the semiconductor substrate below the sacrificial islands, and anisotropically etching the exposed semiconductor substrate using the device isolation layer as an etch mask to form a recessed channel region. The recessed channel region allows the channel width and channel length of a transistor to be increased, thereby reducing the occurrence of short channel effects and narrow channel effects in highly integrated semiconductor devices.

Abstract: Provided is a method of fabricating a semiconductor device having a contact hole with a high aspect-ratio. The method includes: sequentially forming a lower pattern and an upper layer on a semiconductor substrate; sequentially forming a lower mask layer and an upper mask layer on the upper layer; sequentially patterning the lower and upper mask layers to form a hole exposing a top surface of the upper layer on the lower pattern; using the upper mask layer as an etching mask to anisotropically etch the exposed top surface to form an upper contact hole exposing a top surface of the lower pattern; and using the lower mask layer as an etching mask to anisotropically etch the exposed lower pattern to form a lower contact hole in the lower pattern, the lower contact hole extending from the upper contact hole.

Abstract: A stacked semiconductor device and a method for fabricating the stacked semiconductor device are disclosed. The stacked semiconductor device includes a first insulating interlayer having an opening that partially exposes a substrate, wherein the substrate includes single crystalline silicon, and a first seed pattern that fills the opening, wherein the first seed pattern has an upper portion disposed over the opening, and the upper portion is tapered away from the substrate. The stacked semiconductor device further includes a second insulating interlayer formed on the first insulating interlayer, wherein a trench that exposes the upper portion of the first seed pattern penetrates the second insulating interlayer, and a first single crystalline silicon structure that fills the trench.

Abstract: In a semiconductor device and method of manufacturing the semiconductor device, a punch-through prevention film pattern and a channel film pattern are formed on an insulation layer. The punch-through prevention pattern and the insulation layer may include nitride and oxide, respectively. The punch-through prevention pattern is located under the channel pattern.

Abstract: In a method of manufacturing a nonvolatile semiconductor memory device, a preliminary floating gate is formed on a substrate having an active region and an inactive region that extend in a first direction. A dielectric layer and a control gate layer are formed on the substrate. A control gate, a dielectric layer, and a remaining pattern structure are formed by etching the control gate layer and the dielectric layer in a second direction until the preliminary floating gate is partially exposed. The floating gate is formed by etching the preliminary floating gate and the remaining pattern structure until the silicon substrate is exposed. The remaining pattern structure may prevent the isolation layer defining the inactive region from being damaged, thereby suppressing a leakage current in the nonvolatile semiconductor memory device.