Abstract: Provided are methods of manufacturing a semiconductor device. Some embodiments of such methods may include forming a preliminary gate pattern on a substrate. The preliminary gate pattern may include silicon. Methods may include forming an insulation layer pattern on the substrate after forming the preliminary gate pattern. The insulation layer pattern exposes an upper face of the preliminary gate pattern. Methods may include forming a metal layer on the upper face of the preliminary gate pattern via an electroless plating process. Methods may include forming a gate pattern including a metal silicide from a reaction between the preliminary gate pattern and the metal layer by performing a heat treatment process.

Abstract: Disclosed are a variety of methods for increasing the relative thickness in the peripheral or edge regions of gate dielectric patterns to suppress leakage through these regions. The methods provide alternatives to conventional GPOX processes and provide the improved leakage resistance without incurring the degree of increased gate electrode resistance associated with GPOX processes. Each of the methods includes forming a first opening to expose an active area region, forming an oxidation control region on the exposed portion and then forming a second opening whereby a peripheral region free of the oxidation control region is exposed for formation of a gate dielectric layer. The resulting gate dielectric layers are characterized by a thinner central region surrounded or bounded by a thicker peripheral region.

Abstract: A method of forming a buried interconnection includes removing a semiconductor substrate to form a groove in the semiconductor substrate. A metal layer is formed on inner walls of the groove using an electroless deposition technique. A silicidation process is applied to the substrate having the metal layer, thereby forming a metal silicide layer on the inner walls of the groove.

Abstract: A chip electrically connected to wires on a substrate without errors and a flat panel display apparatus including the chip is provided. The chip includes a plurality of bumps that protrude from the chip and have different heights. The flat panel display apparatus may include pads with variable heights on the top of wires of the apparatus.

Abstract: In an embodiment a first silicon pattern and a second silicon pattern are formed on a substrate. The second silicon pattern has a lower top surface than the first silicon pattern. A first spacer covering a sidewall of the first silicon pattern is formed and a second spacer covering a sidewall of the second silicon pattern is formed. A silicide process is performed to silicidize the first silicon pattern and the second silicon pattern. Work functions of the first and second silicon patterns can be controlled and optimized by controlling the composition of the first and second silicon patterns.

Abstract: Methods of forming a microelectronic device can include providing a gate dielectric layer on a channel region of a semiconductor substrate wherein the gate dielectric layer is a high-k dielectric material. A gate electrode barrier layer can be provided on the gate dielectric layer opposite the channel region of the semiconductor substrate, and a gate electrode metal layer can be provided on the gate electrode barrier layer opposite the channel region of the semiconductor substrate. The gate electrode barrier layer and the gate electrode metal layer can be formed of different materials. Moreover, the gate electrode metal layer can include a first material and the gate electrode barrier layer can include a second material, and the first material can have a lower electrical resistivity than the second material.

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: An integrated circuit of a semiconductor device has a line type of pattern that is not prone to serious RC delays. The integrated circuit has a line formed of at least a layer of polycrystalline silicon, a layer of metal having a low sheet resistance, and a layer of a barrier metal interposed between the polycrystalline silicon and the metal having a low sheet resistance, and first spacers disposed on the sides of the line, respectively, and is characterized in that the line has recesses at the sides of the barrier layer and the first spacers fill the recesses. The integrated circuit may constitute a gate line of a semiconductor device. The integrated circuit is formed by forming layers of polycrystalline silicon, metal having a low sheet resistance, and a barrier metal one atop the other, patterning the layers into a line, etching the same to form the recesses, and then forming the first spacers.

Abstract: A heating chamber which can be used during a reflow process to form a metal wiring having a multi-layered writing structure and a method of heating a wafer using the same, are provided. The heating chamber is movable upward and downward between the upper process position and the lower loading position, and includes a pedestal having a supporting surface for supporting a wafer, a cover installed above the pedestal to form a processing area together with the supporting surface when the pedestal is placed in its raised process position and a heating unit for heating the waver. In the method of heating the wafer, the temperature in the processing area is maintained suitable for heating the wafer before the wafer is loaded onto the supporting surface, the wafer is loaded onto the supporting surface and the loaded wafer is heating in the processing area.

Abstract: A flat panel display device that includes a clad unit that may prevent terminals of a pad unit from becoming corroded or damaged by an etching solution during etching. The flat panel display device may include a display unit, a pad unit which may include a plurality of terminals electrically connecting the display unit to external devices, and a clad unit which may cover at least side end portions of the terminals, in which the clad unit may be composed of an insulating material.

Abstract: A method of forming a tungsten silicide layer and a related method of fabricating a semiconductor element. The method of forming the tungsten silicide layer includes forming a pre-coating layer within a CVD process chamber by injecting a tungsten source gas (A) and a silicon source gas (B) at a flow ratio (A/B) of 1/50 or less, and thereafter loading a semiconductor substrate into the CVD process chamber in which the precoating layer is formed, and injecting additional tungsten source gas and silicon source gas to form the tungsten silicide layer on the semiconductor substrate.

Abstract: A method of forming a composite metal silicide layer is disclosed in which a PVD-metal layer is deposited on a silicon layer using a Physical Vapor Deposition (PVD) process, and is substantially simultaneously silicidated to form a PVD-metal silicide layer. Un-reacted portions of the PVD-metal layer are then removed and a CVD-metal layer is formed on the PVD-metal silicide layer using a Chemical Vapor Deposition (CVD) process. A first heat treatment is performed to silicidate a portion of the CVD-metal layer contacting the PVD-metal silicide layer and thereby form a composite metal silicide layer. Un-reacted residual portions of the CVD-metal layer are removed and a second heat treatment is performed on the composite metal silicide layer at a higher temperature than the first heat treatment.

Abstract: Example embodiments relate to a multilayer gate electrode, a semiconductor device having the same and methods of fabricating the same. Other example embodiments relate to a semiconductor device with a multilayer gate electrode which is relatively stable at higher temperatures, has improved resistance characteristics and improved reliability, and methods of fabricating the same. The multilayer gate electrode may include a polycrystalline semiconductor layer on the gate insulating layer and doped with conductive type impurities, an ohmic contact layer on the polycrystalline semiconductor layer and including tungsten (W1?x) and non-tungsten metal (Mx, x=about 0.01 to about 0.55), a metal barrier layer on the ohmic contact layer and a refractory metal layer on the metal barrier layer.

Abstract: A flat panel display comprises: a transparent substrate having a first display portion and a second display portion; at least one first organic light emitting diode positioned in the first display portion for emitting light in a first direction perpendicular to the transparent substrate, and having a first lower electrode, a first upper electrode, and a first organic emission layer interposed between the first lower electrode and the first upper electrode; and at least one second organic light emitting diode positioned in the second display portion for emitting light in a second direction opposite to the first direction, and having a second lower electrode, a second upper electrode, and a second organic emission layer interposed between the second lower electrode and the second upper electrode. As a result, the flat panel display is fabricated using one substrate to display both screens such that one of the screens is displayed while the other is not displayed.

Abstract: Example embodiments of the present invention provide a semiconductor device, a gate electrode and method of manufacturing the same. Other example embodiments of the present invention provide a gate electrode with a refractory metal layer having decreased sheet resistance and increased reliability, a semiconductor device and a method of manufacturing the same. The gate electrode may be formed of a polysilicon layer, an amorphized metal barrier layer formed on the polysilicon layer and/or a refractory metal layer formed on the amorphized metal barrier layer. The polysilicon layer may have a first conductivity type. The semiconductor device may include a semiconductor substrate, a source region, a drain region, a gate insulation layer and/or the gate electrode described above. The source region and the drain region may be formed in the semiconductor substrate. The source and drain regions may have the first conductivity type.

Abstract: A method of forming an integrated circuit device can include forming a plurality of stacked cell gates in a memory cell region of a semiconductor substrate and a plurality of high-voltage transistor gates in a peripheral circuit region of the semiconductor substrate. The semiconductor substrate including both the plurality of stacked cell gates and the plurality of high-voltage transistor gates is annealed and the annealed semiconductor substrate including both the plurality of stacked cell gates and the plurality of high-voltage transistor gates is plasma oxidized.

Abstract: Methods of forming a metal salicide layer can include forming a metal layer on a substrate and forming a metal silicide layer on the metal layer using a first thermal process at a first temperature. Then a second process is performed, in-situ with the first thermal process, on the metal layer at a second temperature that is less than the first temperature.

Abstract: Methods of forming a microelectronic device can include providing a gate dielectric layer on a channel region of a semiconductor substrate wherein the gate dielectric layer is a high-k dielectric material. A gate electrode barrier layer can be provided on the gate dielectric layer opposite the channel region of the semiconductor substrate, and a gate electrode metal layer can be provided on the gate electrode barrier layer opposite the channel region of the semiconductor substrate. The gate electrode barrier layer and the gate electrode metal layer can be formed of different materials. Moreover, the gate electrode metal layer can include a first material and the gate electrode barrier layer can include a second material, and the first material can have a lower electrical resistivity than the second material.

Abstract: Methods of forming a microelectronic device can include providing a gate dielectric layer on a channel region of a semiconductor substrate wherein the gate dielectric layer is a high-k dielectric material. A gate electrode barrier layer can be provided on the gate dielectric layer opposite the channel region of the semiconductor substrate, and a gate electrode metal layer can be provided on the gate electrode barrier layer opposite the channel region of the semiconductor substrate. The gate electrode barrier layer and the gate electrode metal layer can be formed of different materials. Moreover, the gate electrode metal layer can include a first material and the gate electrode barrier layer can include a second material, and the first material can have a lower electrical resistivity than the second material.

Abstract: Atomic layers can be formed by introducing a tantalum amine derivative reactant onto a substrate, wherein the tantalum amine derivative has a formula: Ta(NR1)(NR2R3)3, wherein R1, R2 and R3 are each independently H or a C1-C6 alkyl functional group, chemisorbing a portion of the reactant on the substrate, removing non-chemisorbed reactant from the substrate and introducing a reacting gas onto the substrate to form a solid material on the substrate. Thin films comprising tantalum nitride (TaN) are also provided.