Abstract: Provided are improved methods for forming silicon films, particularly single-crystal silicon films from amorphous silicon films in which a single-crystal silicon substrate is prepared by removing any native oxide, typically using an aqueous HF solution, and placed in a reaction chamber. The substrate is then heated from about 350° C. to a first deposition temperature under a first ambient to induce single-crystal epitaxial silicon deposition primarily on exposed silicon surfaces. The substrate is then heated to a second deposition temperature under a second ambient that will maintain the single-crystal epitaxial silicon deposition on exposed single-crystal silicon while inducing amorphous epitaxial silicon deposition on insulating surfaces. The amorphous epitaxial silicon can then be converted to single-crystal silicon using a solid phase epitaxy process to form a thin, high quality silicon layer.

Abstract: There are provided a high-voltage transistor and a method of forming the same. A channel region of the high-voltage transistor includes a first region and a second region. The first region has high impurity concentration that is higher than that of the second region. In addition, the first region may be in contact with the isolation layer. Thus, it is possible to enhance leakage current characteristics of the high-voltage transistor.

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: In a method of forming a thin-film structure employed in a non-volatile semiconductor device, an oxide film is formed on a substrate. An upper nitride film is formed on the oxide film by nitrifying an upper portion of the oxide film through a plasma nitration process. A lower nitride film is formed between the substrate and the oxide film by nitrifying a lower portion of the oxide film through a thermal nitration process. A damage to the thin-film structure generated in the plasma nitration process may be at least partially cured in the thermal nitration process, and/or may be cured in a post-thermal treatment process.

Abstract: A method of forming an integrated circuit can be provided by successively laterally forming single crystalline thin film regions from an amorphous thin film using a lower single crystalline seed layer.

Abstract: A method of forming a high dielectric film for a semiconductor device comprises supplying a first source gas to a reaction chamber during a first time interval, supplying a first reactant gas to the reaction chamber during a second time interval after the first time interval, supplying a second source gas to the reaction chamber for a third time interval after the second time interval, supplying a second reactant gas to the reaction chamber for a fourth time interval after the third time interval, and supplying an additive gas including nitrogen to the reaction chamber during a fifth time interval.

Abstract: A fin type field effect transistor includes a semiconductor substrate, an active fin, a first hard mask layer pattern, a gate insulation layer pattern, a first conductive layer pattern, and source/drain regions. The active fin includes a semiconductor material and is formed on the substrate and extends in a direction away from a major surface of the substrate. The first hard mask layer pattern is formed on a distal surface of the active fin from the substrate. The gate insulation layer is formed on a sidewall portion of the active fin. The first conductive layer pattern includes a metal silicide and is formed on surfaces of the substrate and the gate insulation layer pattern, and on a sidewall of the first hard mask pattern. The source/drain regions are formed in the active fin on opposite sides of the first conductive layer pattern.

Abstract: Methods of forming a composite layer, a gate structure and a capacitor are disclosed. In the methods, a first dielectric layer is atomic layer deposited on a substrate by using an oxidation gas and a first precursor gas that includes hafnium precursors. A second dielectric layer is then atomic layer deposited on the first dielectric layer by using a nitriding gas and a second precursor gas that includes hafnium precursors.

Abstract: A method of forming a thin layer including providing a first single-crystalline silicon layer partially exposed through an opening in an insulation pattern and forming an epitaxial layer on the first single-crystalline silicon layer and forming an amorphous silicon layer on the insulation pattern, the amorphous silicon layer having a first portion adjacent the epitaxial layer and a second portion spaced apart from the first portion, wherein the amorphous silicon layer is formed on the insulation pattern at substantially the same rate at the first portion and at a second portion. The amorphous silicon layer may be formed to a uniform thickness without a thinning defect.

Abstract: A semiconductor device may include a gate structure having a gate insulation layer formed on a substrate, and a gate electrode formed on the gate insulation layer. A composite barrier layer may be formed on the gate structure.

Abstract: A semiconductor device includes a gate structure on a channel region of a semiconductor substrate adjacent to a source/drain region therein and a surface insulation layer directly on the source/drain region of the substrate adjacent to the gate structure. The device further includes a spacer on a sidewall of the gate structure adjacent to the source/drain region. A portion of the surface insulation layer adjacent the gate structure is sandwiched between the substrate and the spacer. An interface between the surface insulation layer and the source/drain region includes a plurality of interfacial states. Portions of the source/drain region immediately adjacent the interface define a carrier accumulation layer having a greater carrier concentration than other portions thereof. The carrier accumulation layer extends along the interface under the spacer. Related methods are also discussed.

Abstract: A semiconductor device includes a gate pattern disposed on a semiconductor substrate, a gate spacer disposed on both sidewalls of the gate pattern, and a fixed charge layer disposed in the semiconductor substrate below the gate spacer. Elements generating fixed charges are injected into the fixed charge layer. A layer in which carriers induced by the fixed charge layer are accumulated is disposed below the fixed charge layer. The elements are segregated to a substrate of the semiconductor substrate from the inside of the semiconductor substrate by heat.

Abstract: In a fin field effect transistor (FET), an active pattern protrudes in a vertical direction from a substrate and extends across the substrate in a first horizontal direction. A first silicon nitride pattern is formed on the active pattern, and a first oxide pattern and a second silicon nitride pattern are sequentially formed on the substrate and on a sidewall of a lower portion of the active pattern. A device isolation layer is formed on the second silicon nitride pattern, and a top surface of the device isolation layer is coplanar with top surfaces of the oxide pattern and the second silicon nitride pattern. A buffer pattern having an etching selectivity with respect to the second silicon nitride pattern is formed between the first oxide pattern and the second silicon nitride pattern.

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: Disclosed is a fin transistor and a planar transistor and a method of forming the same. The fin transistor and the planar transistor are formed to have gate electrodes with similar thicknesses by selectively recessing a semiconductor substrate in a planar region where the planar transistor is formed.

Abstract: A semiconductor structure including a SiGe layer and a method of fabricating the same are provided. The structure includes a silicon layer heavily doped with impurities. A SiGe layer is disposed on the silicon layer. A strained silicon layer is disposed on the SiGe layer. The impurities may be boron. The boron in the silicon layer may have a concentration of 1016 to 1020/cm3. Boron in the SiGe layer, diffused from the silicon substrate or directly doped, may suppress movement of misfit dislocation occurring in the SiGe layer toward the surface, thereby reducing a threading dislocation density near the surface of the strained silicon layer.

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: Methods of etching a semiconductor substrate may include providing a first gas that is chemically reactive with respect to the semiconductor substrate, and while providing the first gas, providing a second gas different than the first gas. More particularly, a molecule of the second gas may include a hydrogen atom, and the second gas may lower a temperature at which the first gas chemically reacts with the semiconductor substrate. The mixture of the first and second gases may be provided adjacent the semiconductor substrate to etch the semiconductor substrate.

Abstract: The present invention can provide methods of manufacturing a thin film including hafnium titanium oxide. The methods can include introducing a first reactant including a hafnium precursor onto a substrate; chemisorbing a first portion of the first reactant to the substrate, and physisorbing a second portion of the first reactant to the substrate and the chemisorbed first portion of the first reactant; providing a first oxidant onto the substrate; forming a first thin film including hafnium oxide on the substrate; introducing a second reactant including a titanium precursor onto the first thin film; chemisorbing a first portion of the second reactant to the first thin film, and physisorbing a second portion of the second reactant to the first thin film and the chemisorbed first portion of the second reactant; providing a second oxidant onto the first thin film; and forming a second thin film including titanium oxide on the first thin film.

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.