Abstract: A non-volatile memory device having a control gate on top of the second dielectric (interpoly or blocking dielectric), at least a bottom layer of the control gate in contact with the second dielectric being constructed in a material having a predefined high work-function and showing a tendency to reduce its work-function when in contact with a group of certain high-k materials after full device fabrication. At least a top layer of the second dielectric, separating the bottom layer of the control gate from the rest of the second dielectric, is constructed in a predetermined high-k material, chosen outside the group for avoiding a reduction in the work-function of the material of the bottom layer of the control gate. In the manufacturing method, the top layer is created in the second dielectric before applying the control gate.

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 semiconductor device has two transistors of different structure from each other. One of transistors is P-type and the other is N-type. One of the transistors includes a gate structure in which a polysilicon layer contacts a gate insulation film while the other transistor includes a gate structure in which a metal layer contacts a gate insulation film.

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: In a semiconductor device with dual gates and a method of manufacturing the same, a dielectric layer and first and second metallic conductive layers are successively formed on the semiconductor substrate having first and second regions. The second metallic conductive layer which is formed on the first metallic conductive layer of the second region is etched to form a metal pattern. The first metallic conductive layer is etched using the metal pattern as an etching mask. A polysilicon layer is formed on the dielectric layer and the metal pattern. The first gate electrode is formed by etching portions of the polysilicon layer, the metal pattern, and the first metallic conductive layer of the first region. The second gate electrode is formed by etching a portion of the polysilicon layer formed directly on the dielectric layer of the second region.

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: In a semiconductor device with dual gates and a method of manufacturing the same, a dielectric layer and first and second metallic conductive layers are successively formed on the semiconductor substrate having first and second regions. The second metallic conductive layer which is formed on the first metallic conductive layer of the second region is etched to form a metal pattern. The first metallic conductive layer is etched using the metal pattern as an etching mask. A polysilicon layer is formed on the dielectric layer and the metal pattern. The first gate electrode is formed by etching portions of the polysilicon layer, the metal pattern, and the first metallic conductive layer of the first region. The second gate electrode is formed by etching a portion of the polysilicon layer formed directly on the dielectric 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: A semiconductor device has two transistors of different structure from each other. One of transistors is P-type and the other is N-type. One of the transistors includes a gate structure in which a polysilicon layer contacts a gate insulation film while the other transistor includes a gate structure in which a metal layer contacts a gate insulation film.

Abstract: A dual work function semiconductor device and method for fabricating the same are disclosed. In one aspect, a device includes a first and second transistor on a first and second substrate region. The first and second transistors include a first gate stack having a first work function and a second gate stack having a second work function respectively. The first and second gate stack each include a host dielectric, a gate electrode comprising a metal layer, and a second dielectric capping layer therebetween. The second gate stack further has a first dielectric capping layer between the host dielectric and metal layer. The metal layer is selected to determine the first work function. The first dielectric capping layer is selected to determine the second work function.

Abstract: A non-volatile memory device having a control gate on top of the second dielectric (interpoly or blocking dielectric), at least a bottom layer of the control gate in contact with the second dielectric being constructed in a material having a predefined high work-function and showing a tendency to reduce its work-function when in contact with a group of certain high-k materials after full device fabrication. At least a top layer of the second dielectric, separating the bottom layer of the control gate from the rest of the second dielectric, is constructed in a predetermined high-k material, chosen outside the group for avoiding a reduction in the work-function of the material of the bottom layer of the control gate. In the manufacturing method, the top layer is created in the second dielectric before applying the control gate.

Abstract: A method of manufacturing dual work function devices starting from a single metal electrode and the device resulting therefrom are disclosed. In one aspect, the method includes a single-metal-single-dielectric (SMSD) CMOS integration scheme. A single dielectric stack comprising a gate dielectric layer and a dielectric capping layer and one metal layer overlying the dielectric stack are first deposited, forming a metal-dielectric interface. Upon forming the dielectric stack and the metal layer, at least part of the dielectric capping layer is selectively modified by adding work function tuning elements, the part being adjacent to the metal-dielectric interface.

Abstract: A semiconductor device has two transistors of different structure from each other. One of transistors is P-type and the other is N-type. One of the transistors includes a gate structure in which a polysilicon layer contacts a gate insulation film while the other transistor includes a gate structure in which a metal layer contacts a gate insulation film.

Abstract: Some methods that are provided form a composite dielectric structure on a substrate. A first dielectric layer that includes metal and oxygen is formed on a substrate. A preliminary dielectric layer that includes silicon is formed on the first dielectric layer. A plasma nitriding treatment is performed on the preliminary dielectric layer to change it into a second dielectric layer. The composite dielectric structure includes the second dielectric layer and the first dielectric layer. Other methods form a semiconductor device that includes the composite dielectric structure.

Abstract: A semiconductor device comprising a semiconductor substrate having a first impurity region and a second impurity region, a first gate pattern formed on the first impurity region, and a second gate pattern formed on the second impurity region is disclosed. The first gate pattern comprises a first gate insulation layer pattern, a metal layer pattern having a first thickness, and a first polysilicon layer pattern. The second gate pattern comprises a second gate insulation layer pattern, a metal silicide layer pattern having a second thickness smaller than the first thickness, and a second polysilicon layer pattern. The metal silicide layer pattern is formed from a material substantially the same as the material from which the metal layer pattern is formed. A method for manufacturing the semiconductor device is also disclosed.

Abstract: A method of forming transistor gate structures in an integrated circuit device can include forming a high-k gate insulating layer on a substrate including a first region to include PMOS transistors and a second region to include NMOS transistors. A polysilicon gate layer can be formed on the high-k gate insulating layer in the first and second regions. A metal silicide gate layer can be formed directly on the high-k gate insulating layer in the first region and avoiding forming the metal-silicide in the second region. Related gate structures are also disclosed.

Abstract: An electronic device and a process for manufacturing the same are disclosed. In one aspect, the device comprises an electrode comprising a metal compound selected from the group of tantalum carbide, tantalum carbonitride, hafnium carbide and hafnium carbonitride. The device further comprises a high-k dielectric layer of a hafnium oxide comprising nitrogen and silicon, the high-k dielectric layer having a k value of at least 4.0. The device further comprises a nitrogen and/or silicon and/or carbon barrier layer placed between the electrode and the high-k dielectric layer. The nitrogen and/or silicon and/or carbon barrier layer comprises one or more metal oxides, the metal of the metal oxides being selected from the group of lanthanides, aluminium or hafnium.

Abstract: A semiconductor device having a dual gate is formed on a substrate having a dielectric layer. A first metallic conductive layer is formed on the dielectric layer to a first thickness, and annealed to have a reduced etching rate. A second metallic conductive layer is formed on the first metallic conductive layer to a second thickness that is greater than the first thickness. A portion of the second metallic conductive layer formed in a second area of the substrate is removed using an etching selectivity. A first gate structure having a first metallic gate including the first and the second metallic conductive layers is formed in a first area of the substrate. A second gate structure having a second metallic gate is formed in the second area. A gate dielectric layer is not exposed to an etching chemical due to the first metallic conductive layer, so its dielectric characteristics are not degraded.

Abstract: Provided are semiconductor devices and methods of fabricating the semiconductor devices. Embodiments of such methods may include sequentially forming a gate insulation layer and a metal layer on a semiconductor substrate and etching the metal layer to form a metallic residue on the gate insulation layer. Such methods may also include monitoring an etch by-product to detect an etch endpoint for stopping the etching and forming a polysilicon layer on the gate insulation layer including the metallic residue.

Abstract: A method of manufacturing a semiconductor device includes depositing a high-dielectric film on a semiconductor substrate and performing an oxygen plasma treatment on the high-dielectric film deposited on the semiconductor substrate. The method further includes forming an electrode on the oxygen-plasma treated high-dielectric film.