Abstract: Disclosed are a radon measuring apparatus and method. A radon measuring apparatus according to the present invention can comprise: a housing having two separate spaces and through holes formed such that each space communicates with the outside; a probe unit having first and second probe rods which are respectively disposed inside each space in the opposite direction from each other inside the housing; a control unit disposed inside the housing and connected to the probe unit; and a switching unit for controlling the electrical connection between the first and second probe rods.

Abstract: Disclosed are a radon measuring apparatus and method. A radon measuring apparatus according to the present invention can comprise: a housing having two separate spaces and through holes formed such that each space communicates with the outside; a probe unit having first and second probe rods which are respectively disposed inside each space in the opposite direction from each other inside the housing; a control unit disposed inside the housing and connected to the probe unit; and a switching unit for controlling the electrical connection between the first and second probe rods.

Abstract: Gate-all-around integrated circuit devices include first and second source/drain regions on an active area of an integrated circuit substrate. The first and second source/drain regions form p-n rectifying junctions with the active area. A channel region extends between the first and second source/drain regions. An insulated gate electrode surrounds the channel region.

Abstract: In one embodiment, a method of fabricating a semiconductor device having a crystalline semiconductor layer includes preparing a semiconductor substrate and forming a preliminary active pattern on the semiconductor substrate. The preliminary active pattern includes a barrier pattern and a non-single crystal semiconductor pattern. A sacrificial non-single crystal semiconductor layer covers the preliminary active pattern and the semiconductor substrate. By crystallizing the sacrificial non-single crystal semiconductor layer and the non-single crystal semiconductor pattern, using the semiconductor substrate as a seed layer, the sacrificial non-single crystal semiconductor layer and the non-single crystal semiconductor pattern are changed to a sacrificial crystalline semiconductor layer and a crystalline semiconductor pattern, respectively. The crystalline semiconductor pattern and the barrier pattern constitute an active pattern. The sacrificial crystalline semiconductor layer is removed.

Abstract: A multibit electro-mechanical memory device comprises a substrate, a bit line on the substrate, a first interlayer insulating film on the bit line, first and second lower word lines on the first interlayer insulating film, the first and second lower word lines separated horizontally from each other by a trench, a spacer abutting a sidewall of each of the first and second lower word lines, a pad electrode inside a contact hole, first and second cantilever electrodes suspended over first and second lower voids that correspond to upper parts of the first and second lower word lines provided in both sides on the pad electrode, the first and second cantilever electrodes being separated from each other by the trench, and being curved in a third direction that is perpendicular to the first and second direction; a second interlayer insulating film on the pad electrode, first and second trap sites supported by the second interlayer insulating film to have first and second upper voids on the first and second cantilever

Abstract: Gate-all-around integrated circuit devices include first and second source/drain regions on an active area of an integrated circuit substrate. The first and second source/drain regions form p-n rectifying junctions with the active area. A channel region extends between the first and second source/drain regions. An insulated gate electrode surrounds the channel region.

Abstract: In one embodiment, a method of fabricating a semiconductor device having a crystalline semiconductor layer includes preparing a semiconductor substrate and forming a preliminary active pattern on the semiconductor substrate. The preliminary active pattern includes a barrier pattern and a non-single crystal semiconductor pattern. A sacrificial non-single crystal semiconductor layer covers the preliminary active pattern and the semiconductor substrate. By crystallizing the sacrificial non-single crystal semiconductor layer and the non-single crystal semiconductor pattern, using the semiconductor substrate as a seed layer, the sacrificial non-single crystal semiconductor layer and the non-single crystal semiconductor pattern are changed to a sacrificial crystalline semiconductor layer and a crystalline semiconductor pattern, respectively. The crystalline semiconductor pattern and the barrier pattern constitute an active pattern. The sacrificial crystalline semiconductor layer is removed.

Abstract: In a semiconductor memory device and method, resistive-change memory cells are provided, each including a plurality of control transistors formed on different layers and variable resistance devices comprising a resistive-change memory. Each resistive-change memory cell includes a plurality of control transistors formed on different layers, and a variable resistance device formed of a resistive-change memory. In one example, the number of the control transistors is two. The semiconductor memory device includes a global bit line; a plurality of local bit lines connected to or disconnected from the global bit line via local bit line selection circuits which correspond to the local bit lines, respectively; and a plurality of resistive-change memory cell groups storing data while being connected to the local bit lines, respectively.

Abstract: In semiconductor devices, and methods of formation thereof, both planar-type memory devices and vertically oriented thin body devices are formed on a common semiconductor layer. In a memory device, for example, it is desirable to have planar-type transistors in a peripheral region of the device, and vertically oriented thin body transistor devices in a cell region of the device. In this manner, the advantageous characteristics of each type of device can be applied to appropriate functions of the memory device.

Abstract: Gate-all-around integrated circuit devices include first and second source/drain regions on an active area of an integrated circuit substrate. The first and second source/drain regions form p-n rectifying junctions with the active area. A channel region extends between the first and second source/drain regions. An insulated gate electrode surrounds the channel region.

Abstract: In a method of manufacturing a semiconductor device, an active channel pattern is formed on a substrate. The active channel pattern includes preliminary gate patterns and single crystalline silicon patterns that are alternately stacked with each other. A source/drain layer is formed on a sidewall of the active channel pattern. Mask pattern structures including a gate trench are formed on the active channel pattern and the source/drain layer. The patterns are selectively etched to form tunnels. The gate trench is then filled with a gate electrode. The gate electrode surrounds the active channel pattern. The gate electrode is protruded from the active channel pattern. The mask pattern structures are then removed. Impurities are implanted into the source/drain regions to form source/drain regions. A silicidation process is carried out on the source/drain regions to form a metal silicide layer, thereby completing a semiconductor device having a MOS transistor.

Abstract: A multibit electro-mechanical memory device comprises a substrate, a bit line on the substrate, a first interlayer insulating film on the bit line, first and second lower word lines on the first interlayer insulating film, the first and second lower word lines separated horizontally from each other by a trench, a spacer abutting a sidewall of each of the first and second lower word lines, a pad electrode inside a contact hole, first and second cantilever electrodes suspended over first and second lower voids that correspond to upper parts of the first and second lower word lines provided in both sides on the pad electrode, the first and second cantilever electrodes being separated from each other by the trench, and being curved in a third direction that is perpendicular to the first and second direction; a second interlayer insulating film on the pad electrode, first and second trap sites supported by the second interlayer insulating film to have first and second upper voids on the first and second cantilever

Abstract: A memory device includes a first active region on a substrate and first and second source/drain regions on the substrate abutting respective first and second sidewalls of the first active region. A first gate structure is disposed on the first active region between the first and second source/drain regions. A second active region is disposed on the first gate structure between and abutting the first and second source/drain regions. A second gate structure is disposed on the second active region overlying the first gate structure.

Abstract: A FinFET semiconductor device has an active region formed of a semiconductor substrate and projecting from a surface of the substrate. A fin having a first projection and a second projection composed of the active region are arranged in parallel and at each side of a central trench formed in a central portion of the active region. Upper surfaces and side surfaces of the first projection and the second projection comprise a channel region. A channel ion implantation layer is provided at a bottom of the central trench and at a lower portion of the fin. A gate oxide layer is provided on the fin. A gate electrode is provided on the gate oxide layer. A source region and a drain region are provided in the active region at sides of the gate electrode. A method of forming such a device is also provided.

Abstract: A multibit electro-mechanical memory device comprises a substrate, a bit line on the substrate, a first interlayer insulating film on the bit line, first and second lower word lines on the first interlayer insulating film, the first and second lower word lines separated horizontally from each other by a trench, a spacer abutting a sidewall of each of the first and second lower word lines, a pad electrode inside a contact hole, first and second cantilever electrodes suspended over first and second lower voids that correspond to upper parts of the first and second lower word lines provided in both sides on the pad electrode, the first and second cantilever electrodes being separated from each other by the trench, and being curved in a third direction that is perpendicular to the first and second direction; a second interlayer insulating film on the pad electrode, first and second trap sites supported by the second interlayer insulating film to have first and second upper voids on the first and second cantilever

Abstract: A memory device includes a first active region on a substrate and first and second source/drain regions on the substrate abutting respective first and second sidewalls of the first active region. A first gate structure is disposed on the first active region between the first and second source/drain regions. A second active region is disposed on the first gate structure between and abutting the first and second source/drain regions. A second gate structure is disposed on the second active region overlying the first gate structure.

Abstract: Electromechanical non-volatile memory devices are provided including a semiconductor substrate having an upper surface including insulation characteristics. A first electrode pattern is provided on the semiconductor substrate. The first electrode pattern exposes portions of a surface of the semiconductor substrate therethrough. A conformal bit line is provided on the first electrode pattern and the exposed surface of semiconductor substrate. The bit line is spaced apart from a sidewall of the first electrode pattern and includes a conductive material having an elasticity generated by a voltage difference. An insulating layer pattern is provided on an upper surface of the bit line located on the semiconductor substrate. A second electrode pattern is spaced apart from the bit line and provided on the insulating layer pattern. The second electrode pattern faces the first electrode pattern. Related methods are also provided.

Abstract: A transistor includes first and second pairs of vertically overlaid source/drain regions on a substrate. Respective first and second vertical channel regions extend between the overlaid source/drain regions of respective ones of the first and second pairs of overlaid source/drain regions. Respective first and second insulation regions are disposed between the overlaid source/drain regions of the respective first and second pairs of overlaid source/drain regions and adjacent respective ones of the first and second vertical channel regions. Respective first and second gate insulators are disposed on respective ones of the first and second vertical channel regions. A gate electrode is disposed between the first and second gate insulators. The first and second vertical channel regions may be disposed near adjacent edges of the overlaid source/drain regions.

Abstract: A Schottky barrier FinFET device and a method of fabricating the same are provided. The device includes a lower fin body provided on a substrate. An upper fin body having first and second sidewalls which extend upwardly from a center of the lower fin body and face each other is provided. A gate structure crossing over the upper fin body and covering an upper surface of the upper fin body and the first and second sidewalls is provided. The Schottky barrier FinFET device includes a source and a drain which are formed on the sidewalls of the upper fin body adjacent to sidewalls of the gate structure and made of a metal material layer formed on an upper surface of the lower fin body positioned at both sides of the upper fin body, and the source and drain form a Schottky barrier to the lower and upper fin bodies.

Abstract: A multibit electro-mechanical memory device and a method of manufacturing the same include a substrate, a bit line in a first direction on the substrate, a lower word line in a second direction intersecting the first direction, a pad electrode isolated from a sidewall of the lower word line and connected to the bit line, a cantilever electrode expending in the first direction over the lower word line with a lower void therebetween, and connected to the pad electrode and curved in a third direction vertical to the first and second direction by an electrical field induced by a charge applied to the lower word line, a trap site expending in the second direction over the cantilever electrode with an upper void therebetween, and an upper word line to which a charge to curve the cantilever electrode in a direction of the trap site is applied, and on the trap site.