Abstract: A thin film transistor (TFT) array panel with improved contact between the display signal lines and test lines is presented. The TFT array panel includes: gate lines and data lines intersecting each other, switching elements connected to the gate lines and the data lines, and at least one test line disposed near end portions of the gate lines or the data lines. An insulating layer covers the gate lines, the data lines and the switching elements and has first contact holes exposing the end portions of the gate lines or the data lines and second contact holes exposing the test lines. Auxiliary test lines are formed on the insulating layer and commonly connected to conductive layers, wherein the conductive layers connect at least one test line to the gate lines or the data lines via the first and the second contact holes.

Abstract: An array substrate includes a transparent substrate, a switching device, an insulation layer, a pixel electrode, a reflective plate and an inner polarization layer. The transparent substrate has a reflective region and a transmissive region. The switching device is formed in the reflective region. The insulation layer is formed on the transparent substrate to cover the switching device. The insulation layer has a contact hole that exposes a portion of a drain electrode of the switching device. The pixel electrode is electrically connected to the drain electrode of the switching device through the contact hole. The reflective plate is electrically connected to the pixel electrode and is disposed at the reflective region. The inner polarization layer covers the reflective plate. Thus the white luminance and the contrast ratio of an LCD apparatus having the above array substrate are enhanced.

Abstract: A semiconductor memory device having a capacitor is disclosed. The capacitor includes a bottom capacitor surface formed of a silicon-germanium crystalline layer or a dual layer in which a silicon-germanium crystalline layer covers a silicon crystalline layer. The bottom capacitor surface is uneven and is conventionally formed by an epitaxial method. The silicon germanium crystalline layer is approximately 5 to 50 percent germanium content by weight. The method of fabricating the semiconductor memory device comprises: selectively exposing the surface of a crystalline silicon substrate at the region where the capacitor bottom electrode is formed; supplying a source gas to grow a silicon germanium crystalline layer at the surface of the selectively exposed silicon substrate; stacking a dielectric layer over the silicon germanium crystalline layer; and stacking a conductive layer over the dielectric layer to form a capacitor top electrode.

Abstract: A semiconductor memory device having a capacitor is disclosed. The capacitor includes a bottom capacitor surface formed of a silicon-germanium single crystalline layer or a dual layer in which a silicon-germanium single crystalline layer covers a silicon single crystalline layer. The bottom capacitor surface is uneven and is conventionally formed by an epitaxial method. The silicon germanium single crystalline layer is approximately 5 to 50 percent germanium content by weight. The method of fabricating the semiconductor memory device comprises: selectively exposing the surface of a single crystalline silicon substrate at the region where the capacitor bottom electrode is formed; supplying a source gas to grow a silicon germanium single crystalline layer at the surface of the selectively exposed silicon substrate; stacking a dielectric layer over the silicon germanium single crystalline layer; and stacking a conductive layer over the dielectric layer to form a capacitor top electrode.

Abstract: Field effect transistors (FETs) include an integrated circuit substrate having a surface, and a gate on the surface. A pair of recessed regions in the substrate are located beneath the surface. Respective ones of the recessed regions are located on respective opposite sides of the gate. Each of the recessed regions define a sidewall and a floor. An elevated source/drain structure on each of the recessed regions is at least as thick adjacent to the gate as remote from the gate. A gate spacer may be included between the gate and the elevated source/drain region. The gate spacer can comprise an insulating film. Preferably, the source/drain structure extends to the sidewall of the recessed region. The elevated source/drain structure is preferably free of a facet adjacent the gate. The present invention also relates to methods for fabricating a field effect transistors (FET) having an elevated source/drain structure.

Abstract: A device structure of a LDMOSFET has trench type sinker formed using a trench process. A semiconductor layer of a first conductive type is formed within the device structure. A field area is formed in a trench structure on one side of the semiconductor layer and a gate electrode is formed on a given surface of the semiconductor layer. A channel layer of a second conductive type is formed by laterally diffusion from the field area to a width containing both sides of the gate electrode. The source area of LDMOS is electrically connected with the substrate through the sinker. By a piercing through the source area, the sinker divides the source area into two source areas. This division reduces the parasitic resistance as well as parasitic capacitance. In addition, the device structure eliminates the need for high temperature diffusion process and reduces lateral diffusion of the sinker.

Abstract: A trench isolation in a semiconductor device, and a method for fabricating the same, includes: forming a trench having inner sidewalls for device isolation in a silicon substrate; forming an oxide layer on a surface of the silicon substrate that forms the inner sidewalls of the trench; supplying healing elements to the silicon substrate to remove dangling bonds; and filling the trench with a device isolation layer, thereby forming the trench isolation without dangling bonds causing electrical charge traps.

Abstract: A trench isolation in a semiconductor device, and a method for fabricating the same, includes: forming a trench having inner sidewalls for device isolation in a silicon substrate; forming an oxide layer on a surface of the silicon substrate that forms the inner sidewalls of the trench; supplying healing elements to the silicon substrate to remove dangling bonds; and filling the trench with a device isolation layer, thereby forming the trench isolation without dangling bonds causing electrical charge traps.

Abstract: A trench isolation in a semiconductor device, and a method for fabricating the same, includes: forming a trench having inner sidewalls for device isolation in a silicon substrate; forming an oxide layer on a surface of the silicon substrate that forms the inner sidewalls of the trench; supplying healing elements to the silicon substrate to remove dangling bonds; and filling the trench with a device isolation layer, thereby forming the trench isolation without dangling bonds causing electrical charge traps.

Abstract: A trench isolation in a semiconductor device, and a method for fabricating the same, includes: forming a trench having inner sidewalls for device isolation in a silicon substrate; forming an oxide layer on a surface of the silicon substrate that forms the inner sidewalls of the trench; supplying healing elements to the silicon substrate to remove dangling bonds; and filling the trench with a device isolation layer, thereby forming the trench isolation without dangling bonds causing electrical charge traps.

Abstract: A trench isolation in a semiconductor device, and a method for fabricating the same, includes: forming a trench having inner sidewalls for device isolation in a silicon substrate; forming an oxide layer on a surface of the silicon substrate that forms the inner sidewalls of the trench; supplying healing elements to the silicon substrate to remove dangling bonds; and filling the trench with a device isolation layer, thereby forming the trench isolation without dangling bonds causing electrical charge traps.

Abstract: A method of fabricating a semiconductor device using a trench isolation method including a hydrogen annealing step, wherein a photoresist pattern is formed on a semiconductor substrate, a pad insulating layer may be formed before forming the photoresist pattern, the semiconductor substrate is etched using the photoresist pattern as an etching mask to form a trench, and an isolation layer is formed in the trench. To remove damages created in an active region defined by the isolation layer, the semiconductor substrate having the isolation layer is annealed in a hydrogen atmosphere.

Abstract: Field effect transistors (FETs) include an integrated circuit substrate having a surface, and a gate on the surface. A pair of recessed regions in the substrate are located beneath the surface. Respective ones of the recessed regions are located on respective opposite sides of the gate. Each of the recessed regions define a sidewall and a floor. An elevated source/drain structure on each of the recessed regions is at least as thick adjacent to the gate as remote from the gate. A gate spacer may be included between the gate and the elevated source/drain region. The gate spacer can comprise an insulating film. Preferably, the source/drain structure extends to the sidewall of the recessed region. The elevated source/drain structure is preferably free of a facet adjacent the gate. The present invention also relates to methods for fabricating a field effect transistors (FET) having an elevated source/drain structure.

Abstract: An internal clock generating circuit and method for generating an internal clock phase-synchronized to an input clock with minimum delay and at high speed is disclosed. An internal clock generating circuit comprises a first delay control circuit for generating a first clock having the time delay of up to T/2 (where T is a cycle of an input clock) from the input clock and for generating a first variable delay control signal; and a second delay control circuit for generating a second clock in response to the first variable delay control signal, the second clock having the time delay of greater than T/2 from the input clock at an initial state and having the time delay of about T from the input clock in a phase-locked state.

Abstract: A method of forming an HF power device. The method includes forming a semiconductor layer as a first conductive type on a semiconductor substrate; etching the semiconductor layer forming a first trench; doping an impurity in the neighborhood of the first trench forming a first impurity layer; burying a conduction film into the first trench; etching the semiconductor layer forming a second trench; forming a field oxide film buried into the second trench; forming a gate electrode on a surface of the semiconductor layer; forming a source on the surface of the semiconductor layer; forming a drain area on the surface of the semiconductor layer; forming an LLD area on the surface of the semiconductor layer between the drain area and the gate electrode; forming a first metal electrode; and forming a second metal electrode electrically connected to the LDD area.

Abstract: A circuit includes a clock buffer to generate an initial reference clock signal responsive to an external clock signal, a DMC to receive the initial reference clock signal, and an array of forward units to receive a signal from the DMC. The circuit also includes an array of back units that produces a back signal. The back signal is input in a clock driver to produce an internal clock signal. A delay element produces a delayed reference signal responsive to the initial reference clock signal. A plurality of MCCs receive an output of one of the forward units and the delayed reference clock signal. When one of the outputs of the forward units is synchronized with the delayed reference clock signal, one of the back units is thereby activated, which initiates generation of the back signal.

Abstract: A method of forming polycrystalline silicon germanium gate electrode is disclosed. The method include the steps of forming gate insulation layer on a substrate, forming a polycrystalline silicon layer on the gate insulation layer and making a plasma doping of germanium to the polycrystalline silicon layer. Generally, boron is doped to the polycrystalline silicon after the step of the plasma doping of germanium. The process of plasma doping of germanium comprises the step of forming germanium contained plasma and enhancing bias electric potential to substrate for the formulated germanium plasma to be accelerated and injected to the polycrystalline silicon layer revealed. If the present invention is applied to CMOS transistor device, doping mask for the germanium plasma doping can be used.

Abstract: Field effect transistors (FETs) include an integrated circuit substrate having a surface, and a gate on the surface. A pair of recessed regions in the substrate are located beneath the surface. Respective ones of the recessed regions are located on respective opposite sides of the gate. Each of the recessed regions define a sidewall and a floor. An elevated source/drain structure on each of the recessed regions is at least as thick adjacent to the gate as remote from the gate. A gate spacer may be included between the gate and the elevated source/drain region. The gate spacer can comprise an insulating film. Preferably, the source/drain structure extends to the sidewall of the recessed region. The elevated source/drain structure is preferably free of a facet adjacent the gate. The present invention also relates to methods for fabricating a field effect transistors (FET) having an elevated source/drain structure.

Abstract: The invention relates to a semiconductor memory device and a method for generating an internal clock, the circuit of the semiconductor device including: a receiver for receiving an external clock; a delay compensation circuit for receiving an output of the receiver and delaying it by as much as the compensation delay time and control delay time subtracted out of a cycle of the external clock; an external control delay part for delaying an output of the delay compensation circuit by as much as the control delay time and unit increase/decrease delay time in response to an external control code; and an internal clock driver for driving an output of the external control delay part and generating an internal clock centered to externally applied data, thereby performing an accurate timing control to an external clock without loss of performance.

Abstract: A method of fabricating a semiconductor device using a trench isolation method including a hydrogen annealing step, wherein a photoresist pattern is formed on a semiconductor substrate, a pad insulating layer may be formed before forming the photoresist pattern, the semiconductor substrate is etched using the photoresist pattern as an etching mask to form a trench, and an isolation layer is formed in the trench. To remove damages created in an active region defined by the isolation layer, the semiconductor substrate having the isolation layer is annealed in a hydrogen atmosphere.