Abstract: Integrated circuit field effect transistor devices include a substrate having a surface and an active channel pattern on the surface. The active channel pattern includes channels that are stacked upon one another and are spaced apart from one another to define at least one tunnel between adjacent channels. A gate electrode surrounds the channels and extends through the at least one tunnel. A pair of source/drain regions also is provided. Integrated circuit field effect transistors are manufactured, by forming a pre-active pattern on a surface of a substrate. The pre-active pattern includes a series of interchannel layers and channel layers stacked alternately upon each other. Source/drain regions are formed on the substrate at opposite ends of the pre-active pattern. The interchannel layers are selectively removed to form tunnels. A gate electrode is formed in the tunnels and surrounding the channels.

Abstract: A fin field-effect transistor (FinFET) device includes a fin-shaped active region having first and second source/drain regions therein and a channel region therebetween vertically protruding from a semiconductor substrate. A gate electrode is formed on an upper surface and sidewalls of the channel region. First and second source/drain contacts are formed on respective upper surfaces and sidewalls of the first and second source/drain regions of the fin-shaped active region at opposite sides of the gate electrode. The channel region may be narrower than the first and second source/drain regions of the fin-shaped active region.

Abstract: A semiconductor device employs an asymmetrical buried insulating layer, and a method of fabricating the same. The semiconductor device includes a lower semiconductor substrate. An upper silicon pattern is located on the lower semiconductor substrate. The upper silicon pattern includes a channel region, and a source region and a drain region spaced apart from each other by the channel region. A gate electrode is electrically insulated from the upper silicon pattern and intersects over the channel region. A bit line and a cell capacitor are electrically connected to the source region and the drain region, respectively. A buried insulating layer is interposed between the drain region and the lower semiconductor substrate. The buried insulating layer has an extension portion partially interposed between the channel region and the lower semiconductor substrate.

Abstract: According to some embodiments, a semiconductor device includes a lower semiconductor substrate, an upper silicon pattern, and a MOS transistor. The MOS transistor includes a body region formed within the upper silicon pattern and source/drain regions separated by the body region. A buried insulating layer is interposed between the lower semiconductor substrate and the upper silicon pattern. A through plug penetrates the buried insulating layer and electrically connects the body region with the lower semiconductor substrate, the through plug positioned closer to one of the source/drain regions than the other source/drain region. At least some portion of the upper surface of the through plug is positioned outside a depletion layer when a source voltage is applied to the one of the source/drain regions, and the upper surface of the through plug is positioned inside the depletion layer when a drain voltage is applied to the one region.

Abstract: An SOI substrate is fabricated by providing a substrate having a sacrificial layer thereon, an active semiconductor layer on the sacrificial layer remote from the substrate and a supporting layer that extends along at least two sides of the active semiconductor layer and the sacrificial layer and onto the substrate, and that exposes at least one side of the sacrificial layer. At least some of the sacrificial layer is etched through the at least one side thereof that is exposed by the supporting layer to form a void space between the substrate and the active semiconductor layer, such that the active semiconductor layer is supported in spaced-apart relation from the substrate by the supporting layer. The void space may be at least partially filled with an insulator lining.

Abstract: Provided are a stacked integrated circuit device including multiple substrates and a method of manufacturing the same. A first integrated circuit substrate, a first integrated circuit formed on the first integrated circuit substrate, and a first passivation insulating layer are sequentially formed. Then, wafer bonding technique for forming an SOI substrate is used, thereby forming a second integrated circuit substrate on the first passivation insulating layer. While forming a second integrated circuit on the second integrated circuit substrate, at least one device-connecting interconnect electrically connects the first and second Integrated circuits and penetrates the second integrated circuit substrate and the first passivation layer. A second passivation insulating layer is formed on an upper surface of the second integrated circuit.

Abstract: Embodiments of the invention include a partially insulated field effect transistor and a method of fabricating the same. According to some embodiments, a semiconductor substrate is formed by sequentially stacking a bottom semiconductor layer, a sacrificial layer, and a top semiconductor layer. The sacrificial layer may be removed to form a buried gap region between the bottom semiconductor layer and the top semiconductor layer. Then, a transistor may be formed on the semiconductor substrate. The sacrificial layer may be a crystalline semiconductor formed by an epitaxial growth technology.

Abstract: Methods of forming multi fin Field Effect Transistors (FET) can include forming a first fin having opposing sidewalls protruding from a substrate and epitaxially growing second fins on the opposing sidewalls, where the second fins have respective exposed sidewalls protruding from the substrate. The second fins or the first fin can be removed to provide at least one fin for a multi fin FET.

Abstract: A method of manufacturing a transistor according to some embodiments includes sequentially forming a dummy gate oxide layer and a dummy gate electrode on an active region of a semiconductor substrate, ion-implanting a first conductive impurity into source/drain regions to form first impurity regions, and ion-implanting the first conductive impurity to form second impurity regions that are overlapped by the first impurity regions. The method includes forming a pad polysilicon layer on the source/drain regions, sequentially removing the pad polysilicon layer and the dummy gate electrode from a gate region of the semiconductor substrate, annealing the semiconductor substrate, and ion-implanting a second conductive impurity to form a third impurity region in the gate region. The method includes removing the dummy gate oxide layer, forming a gate insulation layer, and forming a gate electrode on the gate region.

Abstract: Unit cells of metal oxide semiconductor (MOS) transistors are provided including an integrated circuit substrate and a MOS transistor on the integrated circuit substrate. The MOS transistor has a source region, a drain region and a gate region, the gate region being between the source region and the drain region. First and second channel regions are provided between the source and drain regions. The channel region is defined by first and second spaced apart protrusions in the integrated circuit substrate separated by a trench region. The first and second protrusions extend away from the integrated circuit substrate and upper surfaces of the first and second protrusions are substantially planar with upper surfaces of the source and drain regions. A gate electrode is provided in the trench region extending on sidewalls of the first and second spaced apart protrusions and on at least a portion of surfaces of the first and second spaced apart protrusions.

Abstract: A method of forming a field effect transistor may include forming a doped layer at a surface of a semiconductor substrate, and forming a groove through the doped layer at the surface of the semiconductor substrate while maintaining portions of the doped layer on opposite sides of the groove. A gate insulating layer may be formed on a surface of the groove, and a gate electrode may be formed on the gate insulating layer in the groove.

Abstract: Etching compositions for selectively etching silicon germanium faster than other silicon containing compositions may be produced by controlling the ratios of de-ionized water used in the etching compositions with respect to the amounts of nitric acid, hydrofluoric acid, and/or acetic acid. Methods for selectively etching silicon germanium without damaging a silicon substrate or a silicon layer are possible using the etching compositions.

Abstract: Unit cells of metal oxide semiconductor (MOS) transistors are provided including an integrated circuit substrate an a MOS transistor on the integrated circuit substrate. The MOS transistor includes a source region, a drain region and a gate. The gate is positioned between the source region and the drain region. A horizontal channel is provided between the source and drain regions. The horizontal channel includes at least two spaced apart horizontal channel regions. Related methods of fabricating MOS transistors are also provided.

Abstract: Unit cells of metal oxide semiconductor (MOS) transistors are provided having an integrated circuit substrate and a MOS transistor on the integrated circuit substrate. The MOS transistor includes a source region, a drain region and a gate. The gate is between the source region and the drain region. A channel region is provided between the source and drain regions. The channel region has a recessed region that is lower than bottom surfaces of the source and drain regions. Related methods of fabricating transistors are also provided.

Abstract: Integrated circuit field effect transistor devices include a substrate having a surface and an active channel pattern on the surface. The active channel pattern includes channels that are stacked upon one another and are spaced apart from one another to define at least one tunnel between adjacent channels. A gate electrode surrounds the channels and extends through the at least one tunnel. A pair of source/drain regions also is provided. Integrated circuit field effect transistors are manufactured, by forming a pre-active pattern on a surface of a substrate. The pre-active pattern includes a series of interchannel layers and channel layers stacked alternately upon each other. Source/drain regions are formed on the substrate at opposite ends of the pre-active pattern. The interchannel layers are selectively removed to form tunnels. A gate electrode is formed in the tunnels and surrounding the channels.

Abstract: A unit cell of a metal oxide semiconductor (MOS) transistor is provided including an integrated circuit substrate and a MOS transistor on the integrated circuit substrate. The MOS transistor has a source region, a drain region and a gate. The gate is between the source region and the drain region. First and second spaced apart buffer regions are provided beneath the source region and the drain region and between respective ones of the source region and integrated circuit substrate and the drain region and the integrated circuit substrate.

Abstract: A double gate MOS transistor includes a substrate active region defined in a semiconductor substrate and a transistor active region located over the substrate active region and overlapped with the substrate active region. At least one semiconductor pillar penetrates the transistor active region and is in contact with the substrate active region. The semiconductor pillar supports the transistor active region so that the transistor active region is spaced apart from the substrate active region. At least one bottom gate electrode fills a space between the transistor active region and the substrate active region. The bottom gate electrode is insulated from the substrate active region, the transistor active region and the semiconductor pillar. At least one top gate electrode crosses over the transistor active region and has at least one end that is in contact with a sidewall of the bottom gate electrode.

Abstract: A semiconductor device includes a semiconductor substrate having a recess therein. A gate insulator is disposed on the substrate in the recess. The device further includes a gate electrode including a first portion on the gate insulator in the recess and a second reduced-width portion extending from the first portion. A source/drain region is disposed in the substrate adjacent the recess. The recess may have a curved shape, e.g., may have hemispherical or ellipsoid shape. The source/drain region may include a lighter-doped portion adjoining the recess. Relate fabrication methods are also discussed.

Abstract: MOS transistors have an active region defined in a portion of a semiconductor substrate, a gate electrode on the active region, and drain and source regions in the substrate. First and second lateral protrusions extend from the lower portions of respective sidewalls of the gate electrode. The drain region has a first lightly-doped drain region under the first lateral protrusion, a second lightly-doped drain region adjacent the first lightly-doped drain region, and a heavily-doped drain region adjacent to the second lightly-doped drain region. The source region similarly has a first lightly-doped source region under the second lateral protrusion, a second lightly-doped source region adjacent the first lightly-doped source region, and a heavily-doped source region adjacent to the second lightly-doped source region. The second lightly-doped regions are deeper than the first lightly-doped regions, and the gate electrode may have an inverted T-shape.

Abstract: An integrated circuit structure can include an isolation structure that electrically isolates an active region of an integrated circuit substrate from adjacent active regions and an insulation layer that extends from the isolation structure to beneath the active region. An epitaxial silicon layer extends from the active region through the insulation layer to a substrate beneath the insulation layer.