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 non-volatile memory device includes a tunnel insulating layer pattern on a channel region of a substrate, a charge trapping layer pattern on the tunnel insulating layer pattern, a blocking layer pattern on the charge trapping layer pattern, and a gate electrode including a conductive layer pattern on the blocking layer pattern and a barrier layer pattern on the conductive layer pattern.

Abstract: A trench isolation method for a semiconductor device, wherein a capping layer formed of an insulating material fills a recess generated at a border edge between an active area and an inactive area. The border edge is defined by a trench filled with insulating material. Filling the recess suppresses defects of the semiconductor device. Reduction of the isolating ability, due to the formation of gate poly residue during the forming of a gate, is prevented. Reduction of the threshold voltage of a transistor, caused by electric field concentration due to the gate poly residue, is suppressed. An oxide layer is also provided which protects an nitride pad during a plasma process.

Abstract: An isolation method for a semiconductor device where an insulating mask layer is formed on desired regions of a semiconductor substrate. A trench is formed to a desired depth in the semiconductor substrate using the insulating mask layer as a mask. An oxide layer is formed on the insulating mask layer and on the sidewall of the trench. A trench liner layer is formed on the oxide layer. An insulating filler layer is formed in the trench in the semiconductor substrate, on which the trench liner layer is formed, so as to fill the trench. The insulating mask layer is removed. According to the isolation method for a semiconductor device, it is possible to reduce dents from occurring along the edge of the trench, reduce a bird's beak type oxide layer from occurring at an interface between the insulating mask layers, decrease the leakage current, or improve the electrical characteristics, such as threshold voltage.

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.

Abstract: A semiconductor device having a trench isolation region including an anti-oxidative liner formed to be thin enough to minimize etch wastage caused by a wet etching solution according to a wet loading effect, and a trench isolation method of forming the same. The semiconductor device includes a silicon substrate and a trench isolation region formed in the silicon substrate. A silicon epitaxial growth layer contacts the silicon substrate at a bottom surface of the trench isolation region and fills the lower half of the trench isolation region. A first oxide layer has an L-shaped cross-section and extends from a sidewall of the trench isolation region to a portion of the bottom surface of the trench isolation region. An anti-oxidative liner has an L-shaped cross-section, and extends between the first oxide layer and the silicon epitaxial growth layer, with its inner surface contacting the silicon epitaxial growth layer.

Abstract: A method of forming a T-shaped isolation layer, a method of forming an elevated salicide source/drain region using the same, and a semiconductor device having the T-shaped isolation layer are provided. In the method of forming the T-shaped isolation layer, an isolation layer having a narrow trench region in the lower portion thereof and a wide trench region in the upper portion thereof is formed on a semiconductor substrate. Also, in the method of forming the elevated salicide source/drain region, the method of forming the T-shaped isolation layer is used. In particular, conductive impurities can also be implanted into the lower portion of the wide trench region which constitutes the head of the T-shaped isolation layer and is extended to both sides from the upper end of the narrow trench region by controlling the depth of the wide trench region in an ion implantation step for forming the source/drain region.

Abstract: A semiconductor device having a trench isolation region including an anti-oxidative liner formed to be thin enough to minimize etch wastage caused by a wet etching solution according to a wet loading effect, and a trench isolation method of forming the same. The semiconductor device includes a silicon substrate and a trench isolation region formed in the silicon substrate. A silicon epitaxial growth layer contacts the silicon substrate at a bottom surface of the trench isolation region and fills the lower half of the trench isolation region. A first oxide layer has an L-shaped cross-section and extends from a sidewall of the trench isolation region to a portion of the bottom surface of the trench isolation region. An anti-oxidative liner has an L-shaped cross-section, and extends between the first oxide layer and the silicon epitaxial growth layer, with its inner surface contacting the silicon epitaxial growth layer.

Abstract: A semiconductor device having a trench isolation region including an anti-oxidative liner formed to be thin enough to minimize etch wastage caused by a wet etching solution according to a wet loading effect, and a trench isolation method of forming the same. The semiconductor device includes a silicon substrate and a trench isolation region formed in the silicon substrate. A silicon epitaxial growth layer contacts the silicon substrate at a bottom surface of the trench isolation region and fills the lower half of the trench isolation region. A first oxide layer has an L-shaped cross-section and extends from a sidewall of the trench isolation region to a portion of the bottom surface of the trench isolation region. An anti-oxidative liner has an L-shaped cross-section, and extends between the first oxide layer and the silicon epitaxial growth layer, with its inner surface contacting the silicon epitaxial growth layer.

Abstract: An isolation method for a semiconductor device where an insulating mask layer is formed on desired regions of a semiconductor substrate. A trench is formed to a desired depth in the semiconductor substrate using the insulating mask layer as a mask. An oxide layer is formed on the insulating mask layer and on the sidewall of the trench. A trench liner layer is formed on the oxide layer. An insulating filler layer is formed in the trench in the semiconductor substrate, on which the trench liner layer is formed, so as to fill the trench. The insulating mask layer is removed. According to the isolation method for a semiconductor device, it is possible to reduce dents from occurring along the edge of the trench, reduce a bird's beak type oxide layer from occurring at an interface between the insulating mask layers, decrease the leakage current, or improve the electrical characteristics, such as threshold voltage.

Abstract: A semiconductor device having a trench isolation region including an anti-oxidative liner formed to be thin enough to minimize etch wastage caused by a wet etching solution according to a wet loading effect, and a trench isolation method of forming the same. The semiconductor device includes a silicon substrate and a trench isolation region formed in the silicon substrate. A silicon epitaxial growth layer contacts the silicon substrate at a bottom surface of the trench isolation region and fills the lower half of the trench isolation region. A first oxide layer has an L-shaped cross-section and extends from a sidewall of the trench isolation region to a portion of the bottom surface of the trench isolation region. An anti-oxidative liner has an L-shaped cross-section, and extends between the first oxide layer and the silicon epitaxial growth layer, with its inner surface contacting the silicon epitaxial growth layer.

Abstract: A method of forming a T-shaped isolation layer, a method of forming an elevated salicide source/drain region using the same, and a semiconductor device having the T-shaped isolation layer are provided. In the method of forming the T-shaped isolation layer, an isolation layer having a narrow trench region in the lower portion thereof and a wide trench region in the upper portion thereof is formed on a semiconductor substrate. Also, in the method of forming the elevated salicide source/drain region, the method of forming the T-shaped isolation layer is used. In particular, conductive impurities can also be implanted into the lower portion of the wide trench region which constitutes the head of the T-shaped isolation layer and is extended to both sides from the upper end of the narrow trench region by controlling the depth of the wide trench region in an ion implantation step for forming the source/drain region.

Abstract: A method of forming a T-shaped isolation layer, a method of forming an elevated salicide source/drain region using the same, and a semiconductor device having the T-shaped isolation layer are provided. In the method of forming the T-shaped isolation layer, an isolation layer having a narrow trench region in the lower portion thereof and a wide trench region in the upper portion thereof is formed on a semiconductor substrate. Also, in the method of forming the elevated salicide source/drain region, the method of forming the T-shaped isolation layer is used. In particular, conductive impurities can also be implanted into the lower portion of the wide trench region which constitutes the head of the T-shaped isolation layer and is extended to both sides from the upper end of the narrow trench region by controlling the depth of the wide trench region in an ion implantation step for forming the source/drain region.

Abstract: A trench isolation method for a semiconductor device, wherein a capping layer formed of an insulating material fills a recess generated at a border edge between an active area and an inactive area. The border edge is defined by a trench filled with insulating material. Filling the recess suppresses defects of the semiconductor device. Reduction of the isolating ability, due to the formation of gate poly residue during the forming of a gate, is prevented. Reduction of the threshold voltage of a transistor, caused by electric field concentration due to the gate poly residue, is suppressed. An oxide layer is also provided which protects an nitride pad during a plasma process.

Abstract: A trench isolation method for a semiconductor device, wherein a capping layer formed of an insulating material fills a recess generated at a border edge between an active area and an inactive area. The border edge is defined by a trench filled with insulating material. Filling the recess suppresses defects of the semiconductor device. Reduction of the isolating ability, due to the formation of gate poly residue during the forming of a gate, is prevented. Reduction of the threshold voltage of a transistor, caused by electric field concentration due to the gate poly residue, is suppressed. An oxide layer is also provided which protects an nitride pad during a plasma process.

Abstract: A multilayer oxide film, including at least two oxide layers having differing stress characteristics, is used in a trench isolation method. Preferably, at least a first one of the oxide layers has tensile stress characteristics and at least a second one of the oxide layers has compressive stress characteristics. Thus, during densification, the overall stress can be reduced. The multilayer film is preferably formed by sequentially stacking first and second oxide films which have opposite stress characteristics. In one example, the first oxide film is a tetra-ethyl-orthosilicate (TEOS)-O.sub.3 based chemical vapor deposition (CVD) oxide film and the second oxide film is selected from the group consisting of TEOS-based plasma-enhanced CVD (PECVD) oxide film, an SiH.sub.4 based PECVD oxide film and a high density plasma (HDP) oxide film. In another embodiment, the first oxide film is an HDP oxide film and the second film is a TEOS-O.sub.3 based CVD oxide film.