Abstract: A semiconductor device includes: an isolation layer for defining a plurality of active areas of a substrate, where the isolation layer is disposed on the substrate; a plurality of buried word lines having upper surfaces that are lower than the upper surfaces of the active areas, being surrounded by the active areas, and extending in a first direction parallel to a main surface of the substrate; a gate dielectric film interposed between the buried word lines and the active areas; and a plurality of buried bit lines having upper surfaces that are lower than the upper surfaces of the plurality of buried word lines and extending parallel to the main surface of the substrate in a second direction that differs from the first direction.

Abstract: A method of fabricating a semiconductor device having a vertical channel transistor, the method including forming a hard mask pattern on a substrate, forming a preliminary active pillar by etching the substrate using the hard mask pattern as an etch mask, reducing a width of the preliminary active pillar to form an active pillar having a width less than that of the hard mask pattern, forming a lower source/drain region by implanting impurity ions into the substrate adjacent to the active pillar using the hard mask pattern as an ion implantation mask, and forming an upper source/drain region on the active pillar and vertically separated from the lower source/drain region.

Abstract: A semiconductor device includes a first active pattern protruding from a substrate, a second active pattern on the first active pattern, a gate electrode enclosing a sidewall of the second active pattern, a conductive layer pattern on the first active pattern, a first impurity region in the first active pattern, and a second impurity region at a surface portion of the second active pattern. The first active pattern extending along a predetermined direction may have a first region and a second region. The second active pattern may have a pillar structure and the conductive layer pattern may include a metal or a metal compound.

Abstract: A vertical pillar transistor may include a plurality of lower pillars, a plurality of upper pillars, a first insulation part, a second insulation part and a word line. The plurality of lower pillars protrudes substantially perpendicular to a substrate and is defined by a plurality of trenches. The plurality of lower pillars extends along a second direction and may be separated from each other along a first direction substantially perpendicular to the second direction. The plurality of upper pillars may be formed on the plurality of lower pillars. The plurality of upper pillars has a width substantially smaller than that of the plurality of lower pillars. The first insulation part has a substantially uniform thickness on a sidewall of each of the plurality of lower pillars. The second insulation part may be formed on the first insulation part to fill a gap between the adjacent upper pillars.

Abstract: A method of manufacturing a local recess channel transistor in a semiconductor device. A hard mask layer is formed on a semiconductor substrate that exposes a portion of the substrate. The exposed portion of the substrate is etched using the hard mask layer as an etch mask to form a recess trench. A trench spacer is formed on the substrate along a portion of sidewalls of the recess trench. The substrate along a lower portion of the recess trench is exposed after the trench spacer is formed. The exposed portion of the substrate along the lower portion of the recess trench is doped with a channel impurity to form a local channel impurity doped region surrounding the lower portion of the recess trench. A portion of the local channel impurity doped region surrounding the lower portion of the recess trench is doped with a Vth adjusting impurity to form a Vth adjusting impurity doped region inside the local channel impurity doped region. The width of the lower portion of the recess trench is expanded.

Abstract: Embodiments prevent or substantially reduce diffusion of a P-type impurity into a channel region in a PMOS transistor having a dual gate. Some embodiments include forming a device isolation film on a semiconductor substrate, forming a channel impurity region in an active region of the semiconductor substrate, and forming a gate insulation layer including a silicon oxide layer and a silicon oxide nitride layer on the semiconductor substrate. Also, the embodiments can include forming a polysilicon layer containing an N-type impurity on the gate insulation layer, and forming a gate electrode by selectively ion-implanting a P-type impurity into the polysilicon layer formed in a PMOS transistor region of the circuit region. The embodiments further include forming a conductive metal layer and a gate upper insulation layer on the gate electrode, and forming a gate stack in a gate region.

Abstract: A semiconductor device includes an insulation layer disposed on a substrate having a first area and a second area, a first wiring disposed on the insulation layer in the first area, a first active structure disposed on the first wiring, a first gate insulation layer enclosing the first upper portion, a first gate electrode disposed on the first gate insulation layer, a first impurity region disposed at the first lower portion, and a second impurity region disposed at the first upper portion. The first wiring may extend in a first direction. The first active structure includes a first lower portion extending in the first direction and a first upper portion protruding from the first lower portion. The first gate electrode may extend in a second direction. The first impurity region may be electrically connected to the first wiring.

Abstract: A method of manufacturing a semiconductor device, the method including providing a substrate, the substrate including single crystalline silicon and having the first region and a second region; growing a pillar from a top surface of the substrate in the first region; forming a vertical channel transistor including a first gate structure such that first gate structure surrounds a central portion of the pillar; and forming a second transistor on the second region of the substrate such that the second transistor includes a second gate structure.

Abstract: A semiconductor memory device includes first and second active pillar structures protruding at an upper part of a substrate, buried bit lines each extending in a first direction, and first gate patterns and second gate patterns each extending in a second direction. The first and second active pillar structures occupy odd-numbered and even-numbered rows, respectively. The first and the second active pillar structures also occupy even-numbered and odd-numbered columns, respectively. The columns of the second active pillar structures are offset in the second direction from the columns of the first active pillar structures. Each buried bit line is connected to lower portions of the first active pillar structures which occupy one of the even-numbered columns and to lower portions of the second active pillar structures which occupy an adjacent one of the odd-numbered columns.

Abstract: A memory device includes an insulation layer, an active pattern, a gate insulation layer and a gate electrode. The insulation layer is formed on a substrate. The active pattern is formed on the insulation layer, and includes two protrusions and a recess between the protrusions. The active pattern includes a first impurity region and a second impurity region at upper portions of the protrusions distal from the substrate, respectively, and a base region at the other portions serving as a floating body for storing data. The gate insulation layer is formed on a surface of the active pattern. The gate electrode is formed on the gate insulation layer, and surrounds a lower portion of the active pattern and partially fills the recess.

Abstract: A method of fabricating a semiconductor device having a capacitorless one-transistor memory cell includes forming a first floating body pattern on a lower insulating layer of a substrate and a first gate pattern crossing over the first floating body pattern and covering sidewalls of the first floating body pattern is formed. The first floating body pattern at both sides of the first gate pattern is partially etched to form a protrusion portion extending between and above the partially etched regions, and first impurity regions are formed in the partially etched regions of the first floating body pattern.

Abstract: Integrated circuit devices are provided including an integrated circuit substrate and a gate on the integrated circuit substrate. The gate has sidewalls. A barrier layer spacer is provided on the sidewalls of the gate. A portion of the barrier layer spacer protrudes from the sidewalls of the gate exposing a lower surface of the barrier layer spacer that faces the integrated circuit substrate. A silicide layer is provided on the portion of the barrier layer spacer protruding from the sidewalls of the gate.

Abstract: Provided is a capacitor-less DRAM device including: an insulating layer formed on a semiconductor substrate; a silicon layer formed on the insulating layer, wherein a trench is formed inside the silicon layer; and an offset spacer formed on both sidewalls of the trench and protruded upward through the silicon layer. A gate insulating layer is formed on a bottom of the trench, and a gate electrode is formed to be buried in the gate insulating layer and in the trench and the offset spacer. A source region and a drain region are formed in the silicon layer on both sides of the offset spacer so as not to overlap with the gate electrode. A channel region is formed in the silicon layer below the gate insulating layer to be self-aligned with the gate electrode.

Abstract: Dynamic random access memory (DRAM) devices including an insulating layer on a semiconductor substrate; a silicon layer on the insulating layer; an active region in the silicon layer; and a unit cell of a transistor on the active region are provided. The DRAM device does not include a capacitor.

Abstract: In a semiconductor device, the semiconductor device may include a first active structure, a first gate insulation layer, a first gate electrode, a first impurity region, a second impurity region and a contact structure. The first active structure may include a first lower pattern in a first region of a substrate and a first upper pattern on the first lower pattern. The first gate insulation layer may be formed on a sidewall of the first upper pattern. The first gate electrode may be formed on the first gate insulation layer. The first impurity region may be formed in the first lower pattern. The second impurity region may be formed in the first upper pattern. The contact structure may surround an upper surface and an upper sidewall of the first upper pattern including the second impurity region. Accordingly, the contact resistance between the contact structure and the second impurity region may be decreased and structural stability of the contact structure may be improved.

Abstract: Disclosed are a substrate support apparatus and an apparatus for examining the seal pattern of an LCD cell. The substrate support apparatus includes a movable stage provided with drawing nozzles for attaching a substrate to an upper surface and adapted to rotate by a predetermined angle; a fixed stage spaced from the movable stage and provided with floating nozzles for ejecting air upward and drawing nozzles for drawing air downward; and a driving device coupled to the movable stage to rotate the movable stage. The apparatus for examining the seal pattern of an LCD cell includes the substrate support apparatus; and a gantry unit including support platforms positioned on both sides of the substrate support apparatus, a bridge positioned above the substrate support apparatus to connect the support platforms, and a correction device coupled to the bridge to examine and repair a seal pattern of a substrate.

Abstract: A method of manufacturing a local recess channel transistor in a semiconductor device. A hard mask layer is formed on a semiconductor substrate that exposes a portion of the substrate. The exposed portion of the substrate is etched using the hard mask layer as an etch mask to form a recess trench. A trench spacer is formed on the substrate along a portion of sidewalls of the recess trench. The substrate along a lower portion of the recess trench is exposed after the trench spacer is formed. The exposed portion of the substrate along the lower portion of the recess trench is doped with a channel impurity to form a local channel impurity doped region surrounding the lower portion of the recess trench. A portion of the local channel impurity doped region surrounding the lower portion of the recess trench is doped with a Vth adjusting impurity to form a Vth adjusting impurity doped region inside the local channel impurity doped region. The width of the lower portion of the recess trench is expanded.

Abstract: In a semiconductor device and associated methods, the semiconductor device includes a substrate, an insulation layer on the substrate, a conductive structure on the insulation layer, the conductive structure including at least one metal silicide film pattern, a semiconductor pattern on the conductive structure, the semiconductor pattern protruding upwardly from the conductive structure, a gate electrode at least partially enclosing the semiconductor pattern, the gate electrode being spaced apart from the conductive structure, a first impurity region at a lower portion of the semiconductor pattern, and a second impurity region at an upper portion of the semiconductor pattern.

Abstract: A vertical pillar transistor may include a plurality of lower pillars, a plurality of upper pillars, a first insulation part, a second insulation part and a word line. The plurality of lower pillars protrudes substantially perpendicular to a substrate and is defined by a plurality of trenches. The plurality of lower pillars extends along a second direction and may be separated from each other along a first direction substantially perpendicular to the second direction. The plurality of upper pillars may be formed on the plurality of lower pillars. The plurality of upper pillars has a width substantially smaller than that of the plurality of lower pillars. The first insulation part has a substantially uniform thickness on a sidewall of each of the plurality of lower pillars. The second insulation part may be formed on the first insulation part to fill a gap between the adjacent upper pillars.

Abstract: A method of manufacturing a local recess channel transistor in a semiconductor device. A hard mask layer is formed on a semiconductor substrate that exposes a portion of the substrate. The exposed portion of the substrate is etched using the hard mask layer as an etch mask to form a recess trench. A trench spacer is formed on the substrate along a portion of sidewalls of the recess trench. The substrate along a lower portion of the recess trench is exposed after the trench spacer is formed. The exposed portion of the substrate along the lower portion of the recess trench is doped with a channel impurity to form a local channel impurity doped region surrounding the lower portion of the recess trench. A portion of the local channel impurity doped region surrounding the lower portion of the recess trench is doped with a Vth adjusting impurity to form a Vth adjusting impurity doped region inside the local channel impurity doped region. The width of the lower portion of the recess trench is expanded.