Abstract: Embodiments of the invention provide a method for removing hydrogen gas from a chamber and a method for performing a semiconductor device fabrication sub-process and removing hydrogen gas from a chamber. The method for removing hydrogen gas from a chamber comprises removing a substrate from a chamber, wherein residual hydrogen gas is disposed in the chamber, injecting oxygen gas or ozone gas into the chamber, producing plasma in the chamber, and removing OH radicals from the chamber.

Abstract: A plasma display device includes a first substrate, an address electrode formed on an upper surface of the fist substrate, a first dielectric layer formed on the upper surface of the first substrate and embedding the address electrode, a second substrate which is transparent and forms a discharge space by being coupled to the first substrate, a plurality of maintaining electrodes formed on a lower surface of the second substrate to form a predetermined angle with the address electrode, each of the maintaining electrodes including first and second electrodes, a second dielectric layer formed on the second substrate where the maintaining electrodes are formed and embedding the maintaining electrodes, at least a portion where an electrical field is concentrated formed between the first and second electrodes constituting the maintaining electrodes, and a partition installed between the first and second substrates for sectioning the discharge space.

Abstract: Semiconductor devices and methods of fabricating the same are provided. A gate insulating film is provided on a semiconductor substrate. A polymetal gate electrode is provided on the gate insulating film. The polymetal gate electrode includes a conductive polysilicon film on the gate insulating film, a first metal silicide film on the conductive polysilicon film, a barrier film on the first metal silicide film, and a metal film on the barrier film. The barrier film includes a titanium nitride (TiN) film on the first metal silicide film and a buffer layer between the TiN film and the metal film.

Abstract: In an ohmic layer and methods of forming the ohmic layer, a gate structure including the ohmic layer and a metal wiring having the ohmic layer, the ohmic layer is formed using tungsten silicide that includes tungsten and silicon with an atomic ratio within a range of about 1:5 to about 1:15. The tungsten silicide may be obtained in a chamber using a reaction gas including a tungsten source gas and a silicon source gas by a partial pressure ratio within a range of about 1.0:25.0 to about 1.0:160.0. The reaction gas may have a partial pressure within a range of about 2.05 percent to about 30.0 percent of a total internal pressure of the chamber. When the ohmic layer is employed for a conductive structure, such as a gate structure or a metal wiring, the conductive structure may have a reduced resistance.

Abstract: In a method of manufacturing a semiconductor device including a polysilicon layer on which a heat treatment is performed in hydrogen atmosphere, a preliminary polysilicon layer is formed on a semiconductor substrate. Fluorine (F) impurities are implanted onto the preliminary polysilicon layer, so that the preliminary polysilicon layer is formed into a polysilicon layer. A main heat treatment is performed on the polysilicon layer, thereby preventing a void caused by the fluorine (F) in the polysilicon layer. A subsidiary heat treatment is further performed on the polysilicon layer prior to the main heat treatment, thereby activating dopants in the polysilicon layer. Electrical characteristics and performance of a semiconductor device are improved since the void is sufficiently prevented in the polysilicon layer.

Abstract: In a method for forming a gate in a semiconductor device, a first preliminary gate structure is formed on a substrate. The first preliminary gate structure includes a gate oxide layer, a polysilicon layer pattern and a tungsten layer pattern sequentially stacked on the substrate. A primary oxidation process is performed using oxygen radicals at a first temperature for adjusting a thickness of the gate oxide layer to form a second preliminary gate structure having tungsten oxide. The tungsten oxide is reduced to a tungsten material using a gas containing hydrogen to form a gate structure. The tungsten oxide may not be formed on the gate structure so that generation of the whiskers may be suppressed. Thus, a short between adjacent wirings may not be generated.

Abstract: Methods of forming field effect transistors according to embodiments of the invention include forming a conductive gate electrode (e.g., polysilicon gate electrode) on a semiconductor substrate and forming a first metal layer on the conductive gate electrode. This first metal layer may include a material selected from a group consisting of nickel, cobalt, titanium, tantalum and tungsten. The first metal layer and the conductive gate electrode are thermally treated for a sufficient duration to convert a first portion of the conductive gate electrode into a first metal silicide region. The first metal layer and the first metal silicide region are then removed to expose a second portion of the conductive gate electrode. A second metal layer is then formed on the second portion of the conductive gate electrode. This second metal layer may include a material selected from a group consisting of nickel, cobalt, titanium, tantalum and tungsten.

Abstract: Methods of forming a semiconductor device may include forming a tunnel oxide layer on a semiconductor substrate, forming a gate structure on the tunnel oxide layer, forming a leakage barrier oxide, and forming an insulating spacer. More particularly, the tunnel oxide layer may be between the gate structure and the substrate, and the gate structure may include a first gate electrode on the tunnel oxide layer, an inter-gate dielectric on the first gate electrode, and a second gate electrode on the inter-gate dielectric with the inter-gate dielectric between the first and second gate electrodes. The leakage barrier oxide may be formed on sidewalls of the second gate electrode. The insulating spacer may be formed on the leakage barrier oxide with the leakage barrier oxide between the insulating spacer and the sidewalls of the second gate electrode. In addition, the insulating spacer and the leakage barrier oxide may include different materials. Related structures are also discussed.

Abstract: A gate structure includes a gate insulation layer on a substrate, a polysilicon layer pattern on the gate insulation layer, a composite metal layer pattern on the polysilicon layer pattern, and a metal silicide layer pattern on a sidewall of the composite metal layer pattern.

Abstract: Methods of forming semiconductor devices are provided. A preliminary gate structure is formed on a semiconductor substrate. The preliminary gate structure includes a gate insulation layer pattern, a polysilicon layer pattern and a conductive layer pattern. A first oxidation process is performed on the preliminary gate structure using an oxygen radical. The first oxidation process is carried out at a first temperature. A second oxidation process is carried out on the oxidized preliminary gate structure to provide a gate structure on the substrate, the second oxidation process being carried out at a second temperature, the second temperature being higher than the first temperature.

Abstract: A semiconductor device includes a first conductive layer on a semiconductor substrate, a dielectric layer including a high-k dielectric material on the first conductive layer, a second conductive layer including polysilicon doped with P-type impurities on the dielectric layer, and a third conductive layer including a metal on the second conductive layer. In some devices, a first gate structure is formed in a main cell region and includes a tunnel oxide layer, a floating gate, a first high-k dielectric layer, and a control gate. The control gate includes a layer of polysilicon doped with P-type impurities and a metal layer. A second gate structure is formed outside the main cell region and includes a tunnel oxide layer, a conductive layer, and a metal layer. A third gate structure is formed in a peripheral cell region and includes a tunnel oxide, a conductive layer, and a high-k dielectric layer having a width narrower than the conductive layer. Method embodiments are also disclosed.

Abstract: In methods of manufacturing semiconductor devices, a preliminary gate oxide layer is formed on a substrate. A surface treatment process is performed on the preliminary gate oxide layer that reduces a diffusion of an oxidizing agent in the preliminary gate oxide layer to form a gate oxide layer on the substrate. A preliminary gate structure is formed on the gate oxide layer. The preliminary gate structure includes a first conductive layer pattern on the gate oxide layer and a second conductive layer pattern on the first conductive layer pattern. An oxidation process is performed on the preliminary gate structure using the oxidizing agent to form an oxide layer on a sidewall of the first conductive layer pattern and on the gate oxide layer, and to round at least one edge portion of the first conductive layer pattern.

Abstract: Embodiments of the present invention include semiconductor devices that can be made with relatively low resistance, and methods of forming the semiconductor devices. A resistance reducing layer is formed between a polysilicon layer and a metal layer. As a result, an interface resistance between the polysilicon layer and the metal layer is greatly reduced and a distribution of the interface resistance is very uniform. As a result, a conductive structure including the resistance reducing layer has a greatly reduced sheet resistance to improve electrical characteristics of a semiconductor device having the conductive structure.

Abstract: A method for forming a gate pattern of a semiconductor device can include isotropically etching a gate insulating layer located between a gate conductive layer pattern and a substrate to recess an exposed side wall of the gate insulating layer pattern beyond a lower corner of the gate conductive layer pattern to form an undercut region. The gate conductive layer pattern can be treated to round off the lower corner.

Abstract: A gate electrode of a transistor can include an interface between a polysilicon conformal layer and a tungsten layer thereon in a trench in a substrate and a capping layer extending across the trench and covering the interface. Related methods are also disclosed.

Abstract: In a method of manufacturing a semiconductor device, a gate structure having a conductive layer pattern is formed on a substrate. The gate structure is then annealed. Oxygen radicals are applied to the gate structure to form an oxide layer on a sidewall of the conductive layer pattern.

Abstract: A transistor structure and a method of forming the same prevent a boundary face of first and second gate electrodes from being oxidized in a subsequent oxidation process, by forming an oxidation inhibition layer in the boundary face. A gate insulation layer is formed on a semiconductor substrate, and a gate stack is obtained by a sequential accumulation of first and second gate electrodes and a capping layer on the gate insulation layer. An oxidation inhibition layer is formed in a sidewall portion of the gate stack, and the oxidation inhibition layer covers a boundary face of the first and second gate electrodes. Source/drain regions are opposite to the gate stack.

Abstract: The present invention relates to dentritic cell-specific polynucleotides and microarrays, particularly to novel polynucleotides highly expressed in dendritic cells, certain dendritic cell subsets and matured dendritic cells and microarrays comprising thereof. With a marrcoarray of this invention, dendritic cells, certain dendritic cells subsets and matured dendritic cells can be detected rapidly and accurately.

Abstract: A plasma display device includes a first substrate, an address electrode formed on an upper surface of the fist substrate, a first dielectric layer formed on the upper surface of the first substrate and embedding the address electrode, a second substrate which is transparent and forms a discharge space by being coupled to the first substrate, a plurality of maintaining electrodes formed on a lower surface of the second substrate to form a predetermined angle with the address electrode, each of the maintaining electrodes including first and second electrodes, a second dielectric layer formed on the second substrate where the maintaining electrodes are formed and embedding the maintaining electrodes, at least a portion where an electrical field is concentrated formed between the first and second electrodes constituting the maintaining electrodes, and a partition installed between the first and second substrates for sectioning the discharge space.

Abstract: A method for fabricating a conductive line pattern for a semiconductor device including the steps of: forming a gate insulation film on the upper surface of a semiconductor substrate; forming a polysilicon layer on the upper surface of the gate insulation film; forming a WNx film on the upper surface of the polysilicon layer; forming a first insulation film on the upper surface of the WNx film; patterning the first insulation film, the WNx film and the polysilicon layer, to form a conductive line pattern; and selectively oxidizing the polysilicon layer. With the method, in view of forming the conductive line pattern in the WNx/poly-Si structure, the thermal treatment processes are reduced in number, so that the thermal stress applied to the conductive line pattern is diminished, and thus, a reliability of the semiconductor device is improved.