Abstract: A recess gate of a semiconductor device is provided, comprising: a substrate having a recess formed therein; a metal layer formed at the bottom of the recess; a polysilicon layer formed over the metal layer; and a source region and a drain region formed adjacent to the polysilicon layer and spaced from the metal layer.

Abstract: A method of fabricating a semiconductor device includes forming a buffer pattern on a substrate, the buffer pattern including germanium, recrystallizing the buffer pattern to form a strained relaxation buffer pattern, and forming a tensile silicon cap on the strained relaxation buffer pattern, the cap being under tensile strain.

Abstract: Provided is a tunneling insulating layer, a flash memory device including the same that increases a program/erase operation speed of the flash memory device and has improved data retention in order to increase reliability of the flash memory device, a memory card and system including the flash memory device, and methods of manufacturing the same. A tunneling insulating layer may include a first region and a second region on the first region, wherein the first region has a first nitrogen atomic percent, the second region has a second nitrogen atomic percent, and the second nitrogen atomic percent is less than the first nitrogen atomic percent.

Abstract: Example embodiments provide a non-volatile semiconductor memory device and method of forming the same. The non-volatile memory device may include a tunnel insulation layer on a semiconductor substrate, a charge storage layer on the tunnel insulation layer, a first blocking insulation layer on the charge storage layer, and a gate electrode on the first blocking insulation layer, wherein the gate electrode includes aluminum and the first blocking insulation layer does not include aluminum.

Abstract: An example embodiment of a non-volatile memory device and an example embodiment of a method of fabricating the same are provided. The non-volatile memory devices includes a tunnel insulation layer on a semiconductor substrate, a charge storage layer on the tunnel insulation layer, a blocking insulation layer including at least one nano dot on the charge storage layer, and a control gate electrode on the blocking insulation layer.

Abstract: Methods of forming an insulating film include forming an insulating film on a substrate. A first impurity is injected into the insulating film using a thermal process under a first set of processing conditions to form a first impurity concentration peak in a lower portion of the insulating film. A second impurity is injected into the insulating film using the thermal process under a second set of processing conditions, different from the first set of processing conditions, to form a second impurity concentration peak in an upper portion of the insulating film. Injecting the first impurity and injecting the second impurity may be carried out without using plasma and the first impurity concentration peak may be higher than the second impurity concentration peak.

Abstract: Fin-Field Effect Transistors (Fin-FETs) are provided. A fin is provided on an integrated circuit substrate. The fin defines a trench on the integrated circuit substrate. A first insulation layer is provided in the trench such that a surface of the first insulation layer is recessed beneath a surface of the fin exposing sidewalls of the fin. A protection layer is provided on the first insulation layer and a second insulation layer is provided on the protection layer in the trench such that protection layer is between the second insulation layer and the sidewalls of the fin.

Abstract: A semiconductor memory device may include a semiconductor substrate with an active region extending in a first direction parallel with respect to a surface of the semiconductor substrate. A pillar may extend from the active region in a direction perpendicular with respect to the surface of the semiconductor substrate with the pillar including a channel region on a sidewall thereof. A gate insulating layer may surround a sidewall of the pillar, and a word line may extend in a second direction parallel with respect to the surface of the semiconductor substrate. Moreover, the first and second directions may be different, and the word line may surround the sidewall of the pillar so that the gate insulating layer is between the word line and the pillar. A contact plug may be electrically connected to the active region and spaced apart from the word line, and a bit line may be electrically connected to the active region through the contact plug with the plurality of bit lines extending in the first direction.

Abstract: Integrated circuit field effect transistors include an integrated circuit substrate and a fin that projects away from the integrated circuit substrate, extends along the integrated circuit substrate, and includes a top that is remote from the integrated circuit substrate. A channel region is provided in the fin that is doped a conductivity type and has a higher doping concentration of the conductivity type adjacent the top than remote from the top. A source region and a drain region are provided in the fin on opposite sides of the channel region, and an insulated gate electrode extends across the fin adjacent the channel region. Related fabrication methods also are described.

Abstract: Semiconductor devices have gate structures on a semiconductor substrate with first spacers on sidewalls of the respective gate structures. First contact pads are positioned between the gate structures and have heights lower than the heights of the gate structures. Second spacers are disposed on sidewalls of the first spacers and on exposed sidewalls of the first contact pads. Second contact pads are disposed on the first contact pads.

Abstract: A method of manufacturing a non-volatile memory device employing a relatively thin polysilicon layer as a floating gate is disclosed, wherein a tunnel oxide layer is formed on a substrate and a polysilicon layer having a thickness of about 35 ? to about 200 ? is then formed on the tunnel oxide layer using a trisilane (Si3H8) gas as a silicon source gas. The tunnel oxide layer and the polysilicon layer are then patterned into a tunnel oxide layer pattern and a polysilicon layer pattern, respectively. A dielectric layer and a conductive layer corresponding to a control gate are subsequently formed on the polysilicon layer pattern. The polysilicon layer is formed using trisilane (Si3H8) gas as a result of which the polysilicon layer may be formed to have a relatively thin thickness while maintaining a thickness uniformity and realizing a superior morphology thus producing a floating gate having enhanced performance.

Abstract: In plasma ion doping operations, a wafer is positioned on a susceptor within a reaction chamber and an ion doping source gas is plasmalyzed in an upper part of the reaction chamber above a major surface of the wafer while supplying a control gas into the reaction chamber in a lower part of the reaction chamber opposite the major surface of the wafer to thereby dope ions into the major surface of the wafer. The ion doping source gas may comprise at least one halide gas, and the control gas may comprise at least one depositing gas, such as a silane gas. In further embodiments, a diluent gas, such as an inert gas, may be supplied to the reaction chamber while supplying the ion doping source gas and the control gas. Related plasma ion doping apparatus are described.

Abstract: A method of forming a semiconductor device may include forming a fin structure extending from a substrate. The fin structure may include first and second source/drain regions and a channel region therebetween, and the first and second source/drain regions may extend a greater distance from the substrate than the channel region. A gate insulating layer may be formed on the channel region, and a gate electrode may be formed on the gate insulating layer so that the gate insulating layer is between the gate electrode and the channel region. Related devices are also discussed.

Abstract: Example embodiments provide a non-volatile memory device and methods of forming the same. The non-volatile memory device may define an active region in a semiconductor substrate, and may include a device isolation layer extending in a first direction, bit lines in the semiconductor substrate, the bit lines extending in a second direction which intersects the first direction; word lines extending in the first direction and covering the active region; and charge storage patterns between the word lines and active region, wherein the charge storage patterns may be in pairs on both edges of the bit lines, and a pair of charge storage patterns may be spaced apart from each other by the word lines.

Abstract: A nonvolatile memory device may include: a tunnel insulating layer on a semiconductor substrate; a charge storage layer on the tunnel insulating layer; a blocking insulating layer on the charge storage layer; and a control gate electrode on the blocking insulating layer. The tunnel insulating layer may include a first tunnel insulating layer and a second tunnel insulating layer. The first tunnel insulating layer and the second tunnel insulating layer may be sequentially stacked on the semiconductor substrate. The second tunnel insulating layer may have a larger band gap than the first tunnel insulating layer. A method for fabricating a nonvolatile memory device may include: forming a tunnel insulating layer on a semiconductor substrate; forming a charge storage layer on the tunnel insulating layer; forming a blocking insulating layer on the charge storage layer; and forming a control gate electrode on the blocking insulating layer.

Abstract: Embodiments of the present invention include heterogeneous substrates, integrated circuits formed on such heterogeneous substrates. The heterogeneous substrates according to certain embodiments of the present invention include a first Group IV semiconductor layer (e.g., silicon), a second Group IV pattern (e.g., a silicon-germanium pattern) that includes a plurality of individual elements on the first Group IV semiconductor layer, and a third Group IV semiconductor layer (e.g., a silicon epitaxial layer) on the second Group IV pattern and on a plurality of exposed portions of the first Group IV semiconductor layer. The second Group IV pattern may be removed in embodiments of the present invention. In these and other embodiments of the present invention, the third Group IV semiconductor layer may be planarized.

Abstract: A semiconductor device includes a first gate structure on a first region of a substrate, the first gate structure including sequentially formed a first insulating layer pattern, a first conductive layer pattern, and a first polysilicon layer pattern doped with first impurities of a first conductivity type, a first source/drain in the first region of the substrate doped with second impurities of a second conductivity type, a second gate structure on a second region of the substrate, the second gate structure including sequentially formed a second insulating layer pattern, a second conductive layer pattern, and a second polysilicon layer pattern doped with third impurities with the first conductivity type, and a second source/drain in the second region of the substrate doped with fourth impurities having a conductivity type opposite the second conductivity.

Abstract: Provided is a method of manufacturing a semiconductor device, in which the thickness of a gate insulating layer of a CMOS device can be controlled. The method can include selectively injecting fluorine (F) into a first region on a substrate and avoiding injecting the fluorine (F) into a second region on the substrate. A first gate insulating layer is formed of oxynitride layers on the first and second regions to have first and second thicknesses, respectively, where the first thickness is less than the second thickness. A second gate insulating layer is formed on the first gate insulating layer and a gate electrode pattern is formed on the second gate insulating layer.

Abstract: Fabrication of a nonvolatile memory device includes sequentially forming a tunnel oxide layer, a first conductive layer, and a nitride layer on a semiconductor substrate. A stacked pattern is formed from the tunnel oxide layer, the first conductive layer, and the nitride layer and a trench is formed in the semiconductor substrate adjacent to the stacked pattern. An oxidation process is performed to form a sidewall oxide layer on a sidewall of the trench and the first conductive layer. Chlorine is introduced into at least a portion of the stacked pattern subjected to the oxidation process. Introducing Cl into the stacked pattern may at least partially cure defects that are caused therein during fabrication of the structure.

Abstract: A method of forming a field effect transistor includes forming a vertical channel protruding from a substrate including a source/drain region junction between the vertical channel and the substrate, and forming an insulating layer extending on a side wall of the vertical channel toward the substrate to beyond the source/drain region junction. The method may also include forming a nitride layer extending on the side wall away from the substrate to beyond the insulating layer, forming a second insulating layer extending on the side wall that is separated from the channel by the nitride layer, and forming a gate electrode extending on the side wall toward the substrate to beyond the source/drain region junction.