Abstract: A semiconductor device includes a substrate having first and second active regions with a field insulating layer therebetween that contacts the first and second active regions, and a gate electrode on the substrate and traversing the first active region, the second active region, and the field insulating layer. The gate electrode includes a first portion over the first active region, a second portion over the second active region, and a third portion in contact with the first and second portions. The gate electrode includes an upper gate electrode having first through third thicknesses in the first through third portions, respectively, where the third thickness is greater than the first thickness, and smaller than the second thickness.

Abstract: A semiconductor device includes a substrate having first and second active regions with a field insulating layer therebetween that contacts the first and second active regions, and a gate electrode on the substrate and traversing the first active region, the second active region, and the field insulating layer. The gate electrode includes a first portion over the first active region, a second portion over the second active region, and a third portion in contact with the first and second portions. The gate electrode includes an upper gate electrode having first through third thicknesses in the first through third portions, respectively, where the third thickness is greater than the first thickness, and smaller than the second thickness.

Abstract: Provided is a semiconductor device with a field effect transistor. The semiconductor device includes a substrate, an active pattern on the substrate, a gate electrode crossing the active pattern and a capping structure on the gate electrode. The capping structure includes first and second capping patterns that are sequentially stacked on the gate electrode. The second capping pattern completely covers a top surface of the first capping pattern, and a dielectric constant of the second capping pattern is greater than that of the first capping pattern.

Abstract: Provided is a semiconductor device with a field effect transistor. The semiconductor device includes a substrate, an active pattern on the substrate, a gate electrode crossing the active pattern and a capping structure on the gate electrode. The capping structure includes first and second capping patterns that are sequentially stacked on the gate electrode. The second capping pattern completely covers a top surface of the first capping pattern, and a dielectric constant of the second capping pattern is greater than that of the first capping pattern.

Abstract: A memory device includes a lower interconnection in a semiconductor substrate, the lower interconnection being made of a material different from the semiconductor substrate, a selection element on the lower interconnection, and a memory element on the selection element.

Abstract: A memory device includes a lower interconnection in a semiconductor substrate, the lower interconnection being made of a material different from the semiconductor substrate, a selection element on the lower interconnection, and a memory element on the selection element.

Abstract: An image sensor includes an active region including a photoelectric conversion region and a floating diffusion region, which are separated from each other, defined by a device isolation region on a semiconductor substrate, and a transfer transistor including a first sub-gate provided on an upper surface of the semiconductor substrate and a second sub-gate extending within a recessed portion of the semiconductor substrate on the active region between the photoelectric conversion region and the floating diffusion region, wherein the photoelectric conversion region includes a plurality of photoelectric conversion elements, which vertically overlap each other within the semiconductor substrate and are spaced apart from the recessed portion.

Abstract: Image sensors include a second photoelectric conversion device disposed in a lower portion of a substrate and a first photoelectric conversion device extending between the secondary photoelectric conversion device and a light receiving surface of the substrate. Electrical isolation between the first and second photoelectric conversion devices is provided by a photoelectron barrier, which may be an optically transparent electrically insulating material. MOS transistors may be utilized to transfer photoelectrons generated within the first and second photoelectric conversion devices to a floating diffusion region within the image sensor. These transistors may represent one example of means for transferring photoelectrons generated in the first and second photoelectric conversion devices to a floating diffusion region in the substrate, in response to first and second gating signals, respectively. The first and second gating signals may be active during non-overlapping time intervals.

Abstract: A memory device includes a lower interconnection in a semiconductor substrate, the lower interconnection being made of a material different from the semiconductor substrate, a selection element on the lower interconnection, and a memory element on the selection element.

Abstract: A phase change memory device includes a vertically-stacked capacitor structure having large capacitance and small area. The phase change memory device includes a phase change memory structure, and the vertically-stacked capacitor structure electrically connected to the phase change memory structure and comprising a first capacitor and a second capacitor that are stacked and electrically connected in parallel to each other.

Abstract: A memory device includes a lower interconnection in a semiconductor substrate, the lower interconnection being made of a material different from the semiconductor substrate, a selection element on the lower interconnection, and a memory element on the selection element.

Abstract: A phase change memory device includes a vertically-stacked capacitor structure having large capacitance and small area. The phase change memory device includes a phase change memory structure, and the vertically-stacked capacitor structure electrically connected to the phase change memory structure and comprising a first capacitor and a second capacitor that are stacked and electrically connected in parallel to each other.

Abstract: Provided are a non-volatile memory device which can be extended in a stack structure and thus can be highly integrated, and a method of manufacturing the non-volatile memory device. The non-volatile memory device includes: at least one first electrode, at least one second electrode crossing the at least one first electrode, at least one data storing layer interposed between the at least one first electrode and the second electrode, at a region in which the at least one first electrode crosses the at least one second electrode and at least one metal silicide layer interposed between the at least one first electrode and the at least one second electrode, at the region in which the at least one first electrode crosses the at least one second electrode.

Abstract: Provided are a non-volatile memory device which can be extended in a stack structure and thus can be highly integrated, and a method of manufacturing the non-volatile memory device. The non-volatile memory device includes: at least one first electrode, at least one second electrode crossing the at least one first electrode, at least one data storing layer interposed between the at least one first electrode and the second electrode, at a region in which the at least one first electrode crosses the at least one second electrode and at least one metal silicide layer interposed between the at least one first electrode and the at least one second electrode, at the region in which the at least one first electrode crosses the at least one second electrode.

Abstract: Provided is a non-volatile memory device having a stacked structure that is easily highly integrated and a method of economically fabricating the non-volatile memory device. The non-volatile memory device may include at least one first electrode and at least one second electrode that cross each other. At least one data storage layer may be disposed on a section where the at least one first electrode and the at least one second electrode cross each other. The at least one first electrode may include a first conductive layer and a first semiconductor layer.

Abstract: A non-volatile memory device having a stack structure, and a method of operating the non-volatile memory device In which the non-volatile memory device includes a plurality of variable resistors arranged in at least one layer. At least one layer selection bit line and a plurality of bit lines coupled to the plurality of the variable resistors are provided. A plurality of selection transistors coupled between the plurality of the bit lines and the plurality of the variable resistors are provided.

Abstract: Image sensors include a second photoelectric conversion device disposed in a lower portion of a substrate and a first photoelectric conversion device extending between the secondary photoelectric conversion device and a light receiving surface of the substrate. Electrical isolation between the first and second photoelectric conversion devices is provided by a photoelectron barrier, which may be an optically transparent electrically insulating material. MOS transistors may be utilized to transfer photoelectrons generated within the first and second photoelectric conversion devices to a floating diffusion region within the image sensor. These transistors may represent one example of means for transferring photoelectrons generated in the first and second photoelectric conversion devices to a floating diffusion region in the substrate, in response to first and second gating signals, respectively. The first and second gating signals may be active during non-overlapping time intervals.

Abstract: A nonvolatile memory device is provided that includes; a first semiconductor layer extending in a first direction, a second semiconductor layer extending in parallel with and separated from the first semiconductor layer, an isolation layer between the first semiconductor layer and second semiconductor layer, a first control gate electrode between the first semiconductor layer and the isolation layer, a second control gate electrode between the second semiconductor layer and the isolation layer, wherein the second control gate electrode and first control gate electrode are respectively disposed at opposite sides of the isolation layer, a first charge storing layer between the first control gate electrode and the first semiconductor layer, and a second charge storing layer between the second control gate electrode and the second semiconductor layer.

Abstract: An image sensor includes an active region including a photoelectric conversion region and a floating diffusion region, which are separated from each other, defined by a device isolation region on a semiconductor substrate, and a transfer transistor including a first sub-gate provided on an upper surface of the semiconductor substrate and a second sub-gate extending within a recessed portion of the semiconductor substrate on the active region between the photoelectric conversion region and the floating diffusion region, wherein the photoelectric conversion region includes a plurality of photoelectric conversion elements, which vertically overlap each other within the semiconductor substrate and are spaced apart from the recessed portion.

Abstract: The non-volatile memory device may include one or more main strings each of which may include first and second substrings which may separately include a plurality of memory cell transistors; and a charge supply line which may be configured to provide charges to or block charges from the first and second substrings of each of the main strings, wherein each of the main strings may include a first ground selection transistor which may be connected to the first substring; a first substring selection transistor which may be connected to the first ground selection transistor; a second ground selection transistor which may be connected to the second substring; and a second substring selection transistor which may be connected to the second ground selection transistor. A method of programming a target cell of the memory device includes activating selection transistors connected to a main string and substring of the target cell.