Abstract: A semiconductor device can include a field insulation layer including a planar major surface extending in first and second orthogonal directions and a protruding portion that protrudes a particular distance from the major surface relative to the first and second orthogonal directions. First and second multi-channel active fins can extend on the field insulation layer, and can be separated from one another by the protruding portion. A conductive layer can extend from an uppermost surface of the protruding portion to cross over the protruding portion between the first and second multi-channel active fins.

Abstract: A fin-shaped active region is defined on a substrate. First and second gate electrodes crossing the fin-shaped active region are arranged. A dummy gate electrode is formed between the first and second gate electrodes. A first drain region is formed between the first gate electrode and the dummy gate electrode. A second drain region is formed between the dummy gate electrode and the second gate electrode. A source region facing the second drain region is formed. A first drain plug relatively close to the dummy gate electrode, relatively far from the second gate electrode, and connected to the second drain region is formed. The second gate electrode is arranged between the second drain region and the source region. Each of the first and second gate electrodes covers a side surface of the fin-shaped active region.

Abstract: A semiconductor device includes a substrate having first, second and third fins longitudinally aligned in a first direction. A first trench extends between the first and second fins, and a second trench extends between the second and third fins. A first portion of field insulating material is disposed in the first trench, and a second portion of field insulating material is disposed in the second trench. An upper surface of the second portion of the field insulating material is recessed in the second trench at a level below uppermost surfaces of the second and third fins. A first dummy gate is disposed on an upper surface of the first portion of the field insulating material, and a second dummy gate at least partially extends into the second trench to the upper surface of the second portion of the field insulating material.

Abstract: A semiconductor device can include a field insulation layer including a planar major surface extending in first and second orthogonal directions and a protruding portion that protrudes a particular distance from the major surface relative to the first and second orthogonal directions. First and second multi-channel active fins can extend on the field insulation layer, and can be separated from one another by the protruding portion. A conductive layer can extend from an uppermost surface of the protruding portion to cross over the protruding portion between the first and second multi-channel active fins.

Abstract: A semiconductor device includes a substrate having a first region and a second region, first and second gate electrodes disposed on the first and second regions, respectively, and first and second source/drain regions disposed on at least one side of the first and second gate electrodes, respectively. The device further includes first and second silicide regions in the first and second source/drain regions, respectively. A contact area between the first silicide region and the first source/drain region is differs in size from a contact area between the second silicide region and the second source/drain region. Methods of fabricating such devices are also provided.

Abstract: A semiconductor device can include a field insulation layer including a planar major surface extending in first and second orthogonal directions and a protruding portion that protrudes a particular distance from the major surface relative to the first and second orthogonal directions. First and second multi-channel active fins can extend on the field insulation layer, and can be separated from one another by the protruding portion. A conductive layer can extend from an uppermost surface of the protruding portion to cross over the protruding portion between the first and second multi-channel active fins.

Abstract: A method of manufacturing iron-based powder includes providing an iron-based molten steel manufactured through a iron making process and a steelmaking process to a tundish; and performing water atomization over the molten steel discharged through a nozzle connected to the tundish. The iron-based powder is manufactured from the molten steel refined after a molten iron tapped from a iron making process is charged into a converter without a pre-treatment process of the molten iron, thus economically providing the highly clean iron-based powder.

Abstract: A semiconductor device, including a substrate having first and second active regions, the first and second active regions being disposed on opposite sides of an isolation structure, and a bit line electrically coupled to a contact plug that is on the isolation structure between the first active region and the second active region, and electrically coupled to an active bridge pattern directly contacting at least one of the first and second active regions, wherein the contact plug is electrically coupled to the first active region and the second active region, and a bottom surface of the active bridge pattern is below a top surface of the first and second active regions.

Abstract: A non-volatile memory device includes field insulating layer patterns on a substrate to define an active region of the substrate, upper portions of the field insulating layer patterns protruding above an upper surface of the substrate, a tunnel insulating layer on the active region, a charge trapping layer on the tunnel insulating layer, a blocking layer on the charge trapping layer, first insulating layers on upper surfaces of the field insulating layer patterns, and a word line structure on the blocking layer and first insulating layers.

Abstract: Provided are non-volatile memory devices and methods of fabricating the same, including improved bit line and contact formation that may reduce resistance and parasitic capacitance, thereby reducing manufacturing costs and improving device performance. The non-volatile memory devices may include a substrate; a plurality of field regions formed on the substrate, each of the field regions including a homogeneous first field and a second field that is divided into two sub regions via a bridge region; an active region formed on the substrate and defined as having a string structure by the field regions, where at least two strings may be connected via one of the bridge regions; and a plurality of shared bit lines may be formed on the field regions and connected to the active region via bit line contacts, where the bit line contacts may be direct contacts.

Abstract: Methods of programming data in a non-volatile memory cell are provided. A memory cell according to some embodiments may include a gate structure that includes a tunnel oxide layer pattern, a floating gate, a dielectric layer and a control gate sequentially stacked on a substrate, impurity regions that are formed in the substrate at both sides of the gate structure, and a conductive layer pattern that is arranged spaced apart from and facing the floating gate. Embodiments of such methods may include applying a programming voltage to the control gate, grounding the impurity regions and applying a fringe voltage to the conductive layer pattern to generate a fringe field in the floating gate.

Abstract: Provided are non-volatile memory devices and methods of fabricating the same, including improved bit line and contact formation that may reduce resistance and parasitic capacitance, thereby reducing manufacturing costs and improving device performance. The non-volatile memory devices may include a substrate; a plurality of field regions formed on the substrate, each of the field regions including a homogeneous first field and a second field that is divided into two sub regions via a bridge region; an active region formed on the substrate and defined as having a string structure by the field regions, where at least two strings may be connected via one of the bridge regions; and a plurality of shared bit lines may be formed on the field regions and connected to the active region via bit line contacts, where the bit line contacts may be direct contacts.

Abstract: In some embodiments, a semiconductor memory device includes a substrate that includes a cell array region and a peripheral circuit region. The semiconductor memory device further includes a device isolation pattern on the substrate. The device isolation pattern defines a first active region and a second active region within the cell array region and a third active region in the peripheral circuit region. The semiconductor memory device further includes a first common source region, a plurality of first source/drain regions, and a first drain region in the first active region. The semiconductor memory device further includes a second common source region, a plurality of second source/drain regions, and a second drain region in the second active region. The semiconductor memory device further includes a third source/drain region in the third active region. The semiconductor memory device further includes a common source line contacting the first and second common source regions.

Abstract: Provided is a nonvolatile memory device having a common bit line structure. The nonvolatile memory device includes multiple unit elements having a NAND cell array structure, arranged in each of multiple memory strings, and each including a control gate and a charge storage layer. Multiple common bit lines are each commonly connected to ends of each of one pair of memory strings among the memory strings. Provided are a first selection transistor having a first driving voltage and multiple second selection transistors connected in series to the first selection transistors and having a second driving voltage that is lower than the first driving voltage. The first selection transistor and the second selection transistors are arranged between the common bit lines and the unit elements of the of memory strings.

Abstract: A method of forming a semiconductor device pattern, a method of forming a charge storage pattern, a non-volatile memory device including a charge storage pattern and a method of manufacturing the same are provided. The method of forming the charge storage pattern including forming a trench on a substrate, and a device isolation pattern in the trench. The device isolation pattern protrudes from a surface of the substrate such that an opening exposing the substrate is formed. A tunnel oxide layer is formed on the substrate in the opening. A preliminary charge storage pattern is formed on the tunnel oxide layer and the device isolation pattern by selective deposition of conductive materials. The preliminary charge storage pattern may be removed from the device isolation pattern. The preliminary charge storage pattern remains only on the tunnel oxide layer to form the charge storage pattern on the substrate.

Abstract: A non-volatile memory device includes a substrate and a tunnel insulation layer pattern, such that each portion of the tunnel insulation pattern extends along a first direction and adjacent portions of the tunnel insulation layer pattern may be separated in a second direction that is substantially perpendicular to the first direction. A non-volatile memory device may include a gate structure formed on the tunnel insulation layer pattern. The gate structure may include a floating gate formed on the tunnel insulation layer pattern along the second direction, a first conductive layer pattern formed on the floating gate in the second direction, a dielectric layer pattern formed on the first conductive layer pattern along the second direction, and a control gate formed on the dielectric layer pattern in the second direction.

Abstract: A non-volatile memory device includes field insulating layer patterns on a substrate to define an active region of the substrate, upper portions of the field insulating layer patterns protruding above an upper surface of the substrate, a tunnel insulating layer on the active region, a charge trapping layer on the tunnel insulating layer, a blocking layer on the charge trapping layer, first insulating layers on upper surfaces of the field insulating layer patterns, and a word line structure on the blocking layer and first insulating layers.

Abstract: A semiconductor device, including a substrate having first and second active regions, the first and second active regions being disposed on opposite sides of an isolation structure, and a bit line electrically coupled to a contact plug that is on the isolation structure between the first active region and the second active region, and electrically coupled to an active bridge pattern directly contacting at least one of the first and second active regions, wherein the contact plug is electrically coupled to the first active region and the second active region, and a bottom surface of the active bridge pattern is below a top surface of the first and second active regions.

Abstract: A method of manufacturing a semiconductor device, including forming a plurality of gate structures on a substrate, the gate structures each including a hard mask pattern stacked on a gate conductive pattern, forming an insulating layer pattern between the gate structures at least partially exposing a top surface of the hard mask pattern, forming a trench that exposes at least a top surface of the gate conductive pattern by selectively removing the hard mask pattern, and forming a silicide layer on the exposed gate conductive pattern.

Abstract: A non-volatile memory device includes field insulating layer patterns on a substrate to define an active region of the substrate, upper portions of the field insulating layer patterns protruding above an upper surface of the substrate, a tunnel insulating layer on the active region, a charge trapping layer on the tunnel insulating layer, a blocking layer on the charge trapping layer, first insulating layers on upper surfaces of the field insulating layer patterns, and a word line structure on the blocking layer and first insulating layers.