Abstract: A high-voltage semiconductor device and a method for manufacturing the same are disclosed. The disclosed high-voltage semiconductor device includes a semiconductor substrate, a first N type well in the semiconductor substrate, a first P type well in the first N type well, second N type wells in the first N type well along a periphery of the first P type well, a gate insulating film and a gate electrode on the first P type well, and first heavily-doped N type impurity regions in the first P type well at opposite sides of the gate electrode.

Abstract: A semiconductor device which may be for a high voltage and a method of manufacturing the same. A semiconductor device may include a first conductivity-type well formed on and/or over a substrate, a second conductivity-type drift region formed on and/or over a first conductivity-type well, an isolation layer formed on and/or over a first conductivity-type well, an isolation layer defining an isolation region and/or an active region, a gate pattern formed on and/or over a predetermined upper surface of a second conductivity-type drift region and/or a first conductivity-type well at an active region of a substrate, and/or second conductivity-type source and/or drain regions formed on and/or over second conductivity-type drift regions at two sides of a gate pattern. A gate pattern and/or a drift region of a semiconductor device may be formed substantially without gaps.

Abstract: A method of performing ion implantation method for a high-voltage device. The method includes defining a logic region and a high-voltage region in a semiconductor substrate, forming a first gate insulation layer on the semiconductor substrate in the logic region and a second gate insulation layer on the semiconductor substrate in the high-voltage region, the second gate insulation layer being thicker than the first gate insulation layer, forming a hollow region in the logic region and a source region in the high-voltage region by implanting first conductive impurities into the logic region and source regions of the semiconductor substrate, and forming a second conductive impurity layer in the logic region by implanting second conductive impurities logic region of the into the semiconductor substrate.

Abstract: A method of manufacturing an LCD driver chip includes forming a heavily doped P-type well and a heavily doped N-type well over a high voltage region of a substrate; and then forming an oxide layer over the heavily doped P-type well and the heavily doped N-type; and then simultaneously forming a first gate electrode over the heavily doped P-type well and a second gate electrode over the heavily doped N-type well including the oxide layer; and then patterning the oxide layer to form a gate insulating layer under the first and second gate electrodes and an oxide layer portion connected to lateral sides of the gate insulating layers; and then forming an insulating layer over the entire surface of the substrate including the first and second gate electrodes and the oxide layer portion; and then forming spacers on sidewalls of the first and second gate electrodes and then removing the oxide layer portion after forming the spacers; and then forming ion implantations regions over the heavily doped P-type well and the

Abstract: Disclosed is an LCD driver IC. The LCD driver IC can include a first conductive type well formed in a substrate, a second conductive type drift region formed in the first conductive type well, a first isolation layer formed in the second conductive type drift region, a gate formed on the substrate at a first side of the first isolation layer, and a second conductive type first ion implantation region formed in the second conductive type drift region between the first isolation layer and the gate.

Abstract: A semiconductor device and a method of fabricating the same are disclosed. The semiconductor device includes a semiconductor substrate having a first area implanted with first conductive type impurities; an isolating film defining a first active area and a second active area in the first area; first LDD areas spaced from each other on the first active area at a first interval and implanted with second conductive type impurities; and second LDD areas spaced from each other on the second active area at a second interval narrower than the first interval and implanted with the second conductive type impurities.

Abstract: Disclosed is a semiconductor device that can be used as a high voltage transistor. The semiconductor device can include a gate electrode on a semiconductor substrate, drift regions in the substrate at opposite sides of the gate electrode, a source region in one of the drift regions and a drain region in the other of the drift regions, and a shallow trench isolation (STI) region in a portion of the drift region between the gate electrode and the drain region. The portion of the drift region below the STI region can have a doping profile in which the concentration of impurities decreases from the concentration at the lower surface of the STI region, and then increases, and then again decreases.

Abstract: A high-voltage semiconductor device and a method for manufacturing the same are disclosed. The disclosed high-voltage semiconductor device includes a semiconductor substrate, a first N type well in the semiconductor substrate, a first P type well in the first N type well, second N type wells in the first N type well along a periphery of the first P type well, a gate insulating film and a gate electrode on the first P type well, and first heavily-doped N type impurity regions in the first P type well at opposite sides of the gate electrode.

Abstract: The present invention provides a high voltage semiconductor device and a method of manufacturing the same. The high voltage semiconductor device includes: a semiconductor substrate; a first high voltage N-type well formed on the semiconductor substrate; a first high voltage P-type well formed inside the first high voltage N-type well; a second high voltage N-type well formed to surround the first high voltage P-type well inside the first high voltage N-type well; a gate dielectric layer and a gate electrode formed to be stacked on the upper of the first high voltage P-type well; and a first N-type high-concentration impurity region formed at both sides of the gate electrode in the first high voltage P-type well, wherein the concentration of the upper region of the first high voltage N-type well is lower than that of the lower region thereof, based on a portion formed with the first high voltage P-type well.

Abstract: A DMOS device and a method for fabricating the same are provided. A drift region and a well region are formed simultaneously to provide a DMOS device with the drift and well regions having the same depth. This DMOS device includes a high voltage transistor area and a low voltage transistor area, a drift diffused region formed in the high voltage transistor area, and a well region formed in the low voltage transistor area. A drift diffused region and a well region in the low voltage area are formed simultaneously to reduce the number of ion implantation processes, thereby simplifying the manufacturing process.

Abstract: A method of performing ion implantation method for a high-voltage device. The method includes defining a logic region and a high-voltage region in a semiconductor substrate, forming a first gate insulation layer on the semiconductor substrate in the logic region and a second gate insulation layer on the semiconductor substrate in the high-voltage region, the second gate insulation layer being thicker than the first gate insulation layer, forming a hollow region in the logic region and a source region in the high-voltage region by implanting first conductive impurities into the logic region and source regions of the semiconductor substrate, and forming a second conductive impurity layer in the logic region by implanting second conductive impurities logic region of the into the semiconductor substrate.

Abstract: A semiconductor device and a method for manufacturing the same are disclosed. The embodiment improves a snapback breakdown voltage and preventing a phenomenon of dashed curves, by forming a gate to be overlapped with first and second drift regions and first and second regions formed in source and drain regions.

Abstract: A semiconductor device and a method of manufacturing the same are provided, capable of minimizing a size of the semiconductor device and inhibiting punch through. According to an embodiment, at least one conductive bar is formed in a substrate between source and drain regions. Thereby, punch through can be inhibited to the utmost to increase breakdown voltage, and thus the electrical properties of the device can be improved. Further, because the punch through is inhibited, the size of the device can be minimized without degrading the electrical properties of the device.