Abstract: Disclosed is a composition for preventing, ameliorating or treating visceral fat obesity containing a Salvia miltiorrhiza radix extract having excellent activity of reducing visceral fat. Disclosed is a composition for preventing, ameliorating or treating visceral fat obesity containing an extract of Salvia miltiorrhiza radix that has efficacy specific for visceral fat when administered to obese model animal mice that have obesity caused by decreased leptin secretion and diet-induced obesity (DIO) mice in which obesity is induced using a high-fat diet. Disclosed is a composition for preventing, ameliorating or treating visceral fat obesity containing an S. miltiorrhiza extract, wherein the S. miltiorrhiza extract inhibits the production of triglyceride (TG) in liver tissue and the blood, indicating that the S. miltiorrhiza extract has inhibitory activity on visceral-fat-type obesity, and the S.

Abstract: The present invention provides a semiconductor device that has reduced a short-channel effect by preventing the effective channel length at the sides of a channel of a transistor from decreasing by forming the length of a gate electrode to be different according to the parts. The semiconductor device according to the present invention includes a semiconductor substrate including active regions where a semiconductor device is to be fabricated and isolation regions for electrically isolating the active regions. A gate electrode is formed to go across the active region. A source and a drain are formed in the active region at both sides of the gate electrode, wherein the length of the gate electrode on the upper surface of the sides of the active region is longer than the length of the gate electrode of the center of the active region.

Abstract: A method for fabricating a MOSFET includes a step of forming an isolation layer on an isolation region of a substrate, to thereby define an active region ion implanting As and P into the active region, and a step of forming a gate on the active region. An ion implanting step of low-concentration impurity using the gate as a mask is performed to form a low-concentration ion-implanted region in a predetermined portion of the substrate which is placed on the right and left sides of the gate. A sidewall spacer on the sides of the gate is formed, and thereafter, and ion implanting high-concentration impurity into the substrate is performed.

Abstract: A method and apparatus for heat-treating a semiconductor substrate to heat different areas of the substrate at different temperatures. The method includes using an apparatus having a chamber of a refractory material; a support plate located at a lower side in the chamber for supporting the semiconductor substrate; a heating device disposed at an upper side in the chamber; and, a heat resistance mask provided between the support plate and fabricated to have different heat transmission rates therein.

Abstract: The present invention provides a semiconductor device that has reduced a short-channel effect by preventing the effective channel length at the sides of a channel of a transistor from decreasing by forming the length of a gate electrode to be different according to the parts. The semiconductor device according to the present invention includes a semiconductor substrate including active regions where a semiconductor device is to be fabricated and isolation regions for electrically isolating the active regions. A gate electrode is formed to go across the active region. A source and a drain are formed in the active region at both sides of the gate electrode, wherein the length of the gate electrode on the upper surface of the sides of the active region is longer than the length of the gate electrode of the center of the active region.

Abstract: A method for fabricating a bipolar device, including the steps of forming an epitaxial growth retarding layer on a substrate at a predetermined angle, forming a collector layer on the substrate so that the collector layer is adjacent the epitaxial growth retarding layer and has an inclined portion formed over an edge portion of the epitaxial growth retarding layer, forming a base layer having an inclined portion on the collector layer, and forming an emitter layer on the inclined portion of the base layer.

Abstract: The present invention provides a semiconductor device that has reduced a short-channel effect by preventing the effective channel length at the sides of a channel of a transistor from decreasing by forming the length of a gate electrode to be different according to the parts. The semiconductor device according to the present invention includes a semiconductor substrate including active regions where a semiconductor device is to be fabricated and isolation regions for electrically isolating the active regions. A gate electrode is formed to go across the active region. A source and a drain are formed in the active region at both sides of the gate electrode, wherein the length of the gate electrode on the upper surface of the sides of the active region is longer than the length of the gate electrode of the center of the active region.

Abstract: The method of fabricating a semiconductor device includes the steps of selectively forming an insulating oxide layer in a semiconductor substrate having a first conductivity type, wherein the semiconductor substrate has first and second regions; forming impurity layers having a second conductivity type in the first and second regions of the semiconductor substrate; forming a first mask layer in the second region of the semiconductor substrate; forming impurity layers having the second conductivity type in the first region of the semiconductor substrate by performing serial ion implantations with different doses of dopants at different acceleration energies; forming a second mask layer in the first region of the semiconductor substrate; and forming impurity layers having the first conductivity type in the second region of the semiconductor substrate by performing serial ion implantations with different doses of dopants at different acceleration energies.

Abstract: A metal-oxide-semiconductor (MOS) device in which the nonuniform dopant concentration in the channel region is obtained by means of ion implantation through a polysilicon gate electrode of nonuniform cross section, which is itself obtained by oxidizing the polysilicon using a semirecessed LOCOS process.

Abstract: A trench or a recess is formed in a predetermined part of a semiconductor substrate. Then, on the side of the trench or recess, a gate with a sidewall is formed by respective etching-back processes. Using the gate as a mask, a low concentration region for the LDD structure is formed. Using the gate and sidewall as a mask, a source region and a drain region are formed. Thus, the channel region makes a right angle with the trench or recess, and the channel region is bent. Further, the channel region is made to be formed so as to be longer than the width of the gate. Since the low concentration region for the LDD structure is formed only in the drain region, the source resistance can be decreased, and a gate with a narrow width can be easily formed. Further, even if the channel length is short, the occurrence of the DIBL phenomenon can be suppressed.

Abstract: In a semiconductor device and method for manufacturing the same, a buried insulating layer is formed on a semiconductor substrate, multiple depletion regions of a first conductivity type are formed on the buried insulating layer and separated from one another, a field oxide layer is formed among the depletion regions of the buried insulating layer, a gate oxide layer is formed on the depletion regions, a gate is formed on the gate oxide layer, impurity regions that are heavily doped with impurities of a second conductivity type is formed in the depletion regions on both sides of the gate to define a source and drain, and a counter doping layer that is lightly doped with impurities of the second conductivity type is formed under the channel defined by a portion of the depletion regions positioned between the impurity regions.

Abstract: Provided with a method of fabricating a semiconductor device including the steps of: selectively forming an insulating oxide layer in a semiconductor substrate having a first conductivity type, wherein the semiconductor substrate has first and second regions; forming impurity layers having a second conductivity type in the first and second regions of the semiconductor substrate; forming a first mask layer in the second region of the semiconductor substrate; forming impurity layers having the second conductivity type in the first region of the semiconductor substrate by performing serial ion implantations with different doses of dopants at different acceleration energies; forming a second mask layer in the first region of the semiconductor substrate; and forming impurity layers having the first conductivity type in the second region of the semiconductor substrate by performing serial ion implantations with different doses of dopants at different acceleration energies.

Abstract: A SOI device in which floating body effect is reduced to improve performance. The SOI device including a semiconductor substrate; a first buried insulating film formed on the semiconductor substrate; a first conductivity type silicon layer formed on the first buried insulating film; an active region and a first conductivity type semiconductor layer formed to be isolated on predetermined areas of the first conductivity type silicon layer; second buried insulating films formed to be isolated from one another in the first conductivity type silicon layer to connect the first conductivity type semiconductor layer with the active region through the first conductivity type silicon layer; a gate electrode formed on the active region; impurity region formed in the semiconductor substrate at both sides of the gate electrode; and contact pads formed on the first conductivity type silicon layer.

Abstract: A semiconductor device and a method for fabricating the same are disclosed, in which floating body effect is reduced by applying a bias to a body in an SOI MOSFET. The semiconductor device includes first and second impurity ion implanting layers of a conductivity type formed in a semiconductor substrate having a buried oxide film and surface silicon layers thereon, first and second transistors of a conductivity type respectively formed on the first and second impurity ion implanting layers, having source/drain regions and a gate, trenches formed between the first and second transistors, single crystal silicon layers connected to any one of the source/drain regions of the respective transistors and the first and second impurity ion implanting layers at sides of the trenches, and carrier exhausting electrodes connected to the first and second impurity ion implanting layers at one sides of the respective transistors, for exhausting carrier generated by ionization impact in the respective transistors.

Abstract: A trench or a recess is formed in a predetermined part of a semiconductor substrate. Then, on the side of the trench or recess, a gate with a sidewall is formed by respective etching-back processes. Using the gate as a mask, a low concentration region for the LDD structure is formed. Using the gate and sidewall as a mask, a source region and a drain region are formed. Thus, the channel region makes a right angle with the trench or recess, and the channel region is bent. Further, the channel region is made to be formed so as to be longer than the width of the gate. Since the low concentration region for the LDD structure is formed only in the drain region, the source resistance can be decreased, and a gate with a narrow width can be easily formed. Further, even if the channel length is short, the occurrence of the DIBL phenomenon can be suppressed.

Abstract: A method for fabricating an embedded semiconductor device in which a logic device and a memory device are integrated into one semiconductor substrate is disclosed, which includes the steps of forming a device isolation region and active region on a semiconductor substrate having a first region and a second region, forming a gate insulation film on a predetermined portion of an upper surface of the active region of the first region and second region, forming a first conductive film pattern and a protection film pattern on the gate insulation film, forming a first side wall spacer on the lateral surfaces of the first conductive film pattern and the protection film pattern, forming source/drain by implanting a dopant into the surface of the semiconductor substrate at both sides of the first side wall spacer, forming a second side wall spacer on an outer surface of the first side wall spacer, removing the protection film pattern, and forming a second conductive film pattern on the upper surfaces of the first cond

Abstract: In a semiconductor device and method for manufacturing the same, a buried insulating layer is formed on a semiconductor substrate, multiple depletion regions of a first conductivity type are formed on the buried insulating layer and separated from one another, a field oxide layer is formed among the depletion regions of the buried insulating layer, a gate oxide layer is formed on the depletion regions, a gate is formed on the gate oxide layer, impurity regions that are heavily doped with impurities of a second conductivity type is formed in the depletion regions on both sides of the gate to define a source and drain, and a counter doping layer that is lightly doped with impurities of the second conductivity type is formed under the channel defined by a portion of the depletion regions positioned between the impurity regions.

Abstract: A semiconductor device fabrication method and resulting device in which a gate insulating film is formed on a semiconductor substrate, a gate electrode is formed on the gate insulating film, a gate cap is formed on the gate electrode, a heavy density impurity region is formed in the substrate and outside the gate electrode, first side walls are formed on sides of the gate electrode, the gate cap and the gate insulating film. The substrate outside the gate insulating film is etched down to a portion having a highest impurity density, and a light doping region surrounding the heavy impurity region is formed in the substrate. The method and resulting device prevents a hot carrier from being injected into a gate oxide film or a side wall, and reduces the generation of a junction current leakage and a short channel.

Abstract: The method of fabricating a semiconductor device includes the steps of selectively forming an insulating oxide layer in a semiconductor substrate having a first conductivity type, wherein the semiconductor substrate has first and second regions; forming impurity layers having a second conductivity type in the first and second regions of the semiconductor substrate; forming a first mask layer in the second region of the semiconductor substrate; forming impurity layers having the second conductivity type in the first region of the semiconductor substrate by performing serial ion implantations with different doses of dopants at different acceleration energies; forming a second mask layer in the first region of the semiconductor substrate; and forming impurity layers having the first conductivity type in the second region of the semiconductor substrate by performing serial ion implantations with different doses of dopants at different acceleration energies.

Abstract: The present invention provides a semiconductor device that has reduced a short-channel effect by preventing the effective channel length at the sides of a channel of a transistor from decreasing by forming the length of a gate electrode to be different according to the parts. The semiconductor device according to the present invention includes a semiconductor substrate including active regions where a semiconductor device is to be fabricated and isolation regions for electrically isolating the active regions. A gate electrode is formed to go across the active region. A source and a drain are formed in the active region at both sides of the gate electrode, wherein the length of the gate electrode on the upper surface of the sides of the active region is longer than the length of the gate electrode of the center of the active region.