Abstract: Provided are a CMOS transistor, a semiconductor device having the transistor, and a semiconductor module having the device. The CMOS transistor may include first and second interconnection structures respectively disposed in first and second regions of a semiconductor substrate. The first and second regions of the semiconductor substrate may have different conductivity types. The first and second interconnection structures may be disposed on the semiconductor substrate. The first interconnection structure may have a different stacked structure from the second interconnection structure. The CMOS transistor may be disposed in the semiconductor device. The semiconductor device may be disposed in the semiconductor module.

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: A method of fabricating a semiconductor device having a dual gate allows for the gates to have a wide variety of threshold voltages. The method includes forming a gate insulation layer, a first capping layer, and a barrier layer in the foregoing sequence across a first region and a second region on a substrate, exposing the gate insulation layer on the first region by removing the first capping layer and the barrier layer from the first region, forming a second capping layer on the gate insulation layer in the first region and on the barrier layer in the second region, and thermally processing the substrate on which the second capping layer is formed. The thermal processing causes material of the second capping layer to spread into the gate insulation layer in the first region and material of the first capping layer to spread into the gate insulation layer in the second region. Thus, devices having different threshold voltages can be formed in the first and second regions.

Abstract: A complementary metal oxide semiconductor (CMOS) device including: a semiconductor substrate including a NMOS region and a PMOS region; a NMOS metal gate stack structure on the NMOS region and including a first high dielectric layer, a first barrier metal gate on the first high dielectric layer and including a metal oxide nitride layer, and a first metal gate on the first barrier metal gate; and a PMOS metal gate stack structure on the PMOS region and including a second high dielectric layer, a second barrier metal gate on the second high dielectric layer and including a metal oxide nitride layer, and a second metal gate on the second barrier metal gate.

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: A method of fabricating a semiconductor device having a dual gate allows for the gates to have a wide variety of threshold voltages. The method includes forming a gate insulation layer, a first capping layer, and a barrier layer in the foregoing sequence across a first region and a second region on a substrate, exposing the gate insulation layer on the first region by removing the first capping layer and the barrier layer from the first region, forming a second capping layer on the gate insulation layer in the first region and on the barrier layer in the second region, and thermally processing the substrate on which the second capping layer is formed. The thermal processing causes material of the second capping layer to spread into the gate insulation layer in the first region and material of the first capping layer to spread into the gate insulation layer in the second region. Thus, devices having different threshold voltages can be formed in the first and second regions.

Abstract: The method involves providing a semiconductor substrate comprising first and second regions in which different conductive metal-oxide semiconductor (MOS) transistors are to be formed. A gate dielectric layer above the semiconductor substrate sequentially forming a first metallic conductive layer and a second metallic conductive layer on and above the gate dielectric layer; covering the second region with a mask, and performing ion plantation of a first material into the first metallic conductive layer of the first region. Removing the second metallic conductive layer of the first region and forming a first gate electrode of the first region and a second gate electrode of the second region by patterning the gate dielectric layer and the first metallic conductive layer of the first region, and the gate dielectric layer, the first metallic conductive layer, and the second metallic conductive layer of the second region.

Abstract: A semiconductor device that has a dual gate having different work functions is simply formed by using a selective nitridation. A gate insulating layer is formed on a semiconductor substrate including a first region and a second region, on which devices having different threshold voltages are to be formed. A diffusion inhibiting material is selectively injected into the gate insulating layer in one of the first region and the second region. A diffusion layer is formed on the gate insulating layer. A work function controlling material is directly diffused from the diffusion layer to the gate insulating layer using a heat treatment, wherein the gate insulting layer is self-aligned capped with the selectively injected diffusion inhibiting material so that the work function controlling material is diffused into the other of the first region and the second region. The gate insulating layer is entirely exposed by removing the diffusion layer. A gate electrode layer is formed on the exposed gate insulating layer.

Abstract: The memory device includes a first tunnel insulation layer pattern on a semiconductor substrate, a second tunnel insulation layer pattern having an energy band gap lower than that of the first tunnel insulation layer pattern on the first tunnel insulation layer pattern, a charge trapping layer pattern on the second tunnel insulation layer pattern, a blocking layer pattern on the charge trapping layer pattern, and a gate electrode on the blocking layer pattern. The memory device further includes a source/drain region at an upper portion of the semiconductor substrate. The upper portion of the semiconductor substrate is adjacent to the first tunnel insulation layer pattern.

Abstract: Semiconductor devices having a transistor and methods of fabricating such devices are disclosed. The device may include a gate pattern formed on a substrate, spacers formed on sidewalls of the gate pattern, a surface insulation layer that may contact the substrate is interposed between the spacers and the substrate. An inversion layer is provided in the surface region of the substrate under the surface insulation layer. The surface insulation layer is formed of a material generating large quantities of surface states at an interface between the substrate and the surface insulation layer.

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: 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: The memory device includes a first tunnel insulation layer pattern on a semiconductor substrate, a second tunnel insulation layer pattern having an energy band gap lower than that of the first tunnel insulation layer pattern on the first tunnel insulation layer pattern, a charge trapping layer pattern on the second tunnel insulation layer pattern, a blocking layer pattern on the charge trapping layer pattern, and a gate electrode on the blocking layer pattern. The memory device further includes a source/drain region at an upper portion of the semiconductor substrate, The upper portion of the semiconductor substrate is adjacent to the first tunnel insulation layer pattern.

Abstract: A semiconductor device may include a semiconductor substrate and first and second transistors. The first transistor may have a first gate structure on the semiconductor substrate, and the first gate structure may include a first gate insulating layer between a first gate electrode and the semiconductor substrate. The first gate insulating layer may include first and second dielectric materials with the second dielectric material having a greater dielectric constant than the first dielectric material. Moreover, the first gate electrode may be in contact with the second dielectric material. The second transistor may have a second gate structure on the semiconductor substrate, with the second gate structure including a second gate insulating layer between a second gate electrode and the semiconductor substrate. Related methods are also discussed.

Abstract: Oxide layers, including gate oxide layers having different thicknesses, are formed, plasma nitridized, and oxidized in an oxygen atmosphere containing hydrogen at a high temperature. Electron trap sites and stress occurring during plasma nitridation may be removed during oxidation.

Abstract: A method of forming an oxide layer on a semiconductor substrate includes thermally oxidizing a surface of the substrate to form an oxide layer on the substrate, and then exposing the oxide layer to an ambient including predominantly oxygen radicals to thereby thicken the oxide layer. Related methods of fabricating a recessed gate transistor are also discussed.

Abstract: A method of forming an oxide layer on a semiconductor substrate includes thermally oxidizing a surface of the substrate to form an oxide layer on the substrate, and then exposing the oxide layer to an ambient including predominantly oxygen radicals to thereby thicken the oxide layer. Related methods of fabricating a recessed gate transistor are also discussed.

Abstract: Oxide layers, including gate oxide layers having different thicknesses, are formed, plasma nitridized, and oxidized in an oxygen atmosphere containing hydrogen at a high temperature. Electron trap sites and stress occurring during plasma nitridation may be removed during oxidation.

Abstract: A gate insulating layer in an integrated circuit device is formed by forming a gate insulating layer on a substrate. The gate insulating layer is nitrified with plasma and then annealed using oxygen radicals. The oxygen radicals may cure defects in the gate insulating layer caused by the nitridation process. As a result, leakage current may be reduced.