Abstract: The semiconductor device includes a fuse structure disposed on a substrate. An interlayer dielectric disposed on the fuse structure. A first contact plug, a second contact plug, and a third contact plug penetrate the interlayer dielectric and wherein each of the first contact plug, the second contact plug and the third contact plug are connected to the fuse structure. A first conductive pattern and a second conductive pattern are disposed on the interlayer dielectric. The first conductive pattern and the second conductive pattern are electrically connected to the first contact plug and second contact plug, respectively.

Abstract: A method of manufacturing a semiconductor device, the method including providing a semiconductor substrate; forming a gate pattern on the semiconductor substrate such that the gate pattern includes a gate dielectric layer and a sacrificial gate electrode; forming an etch stop layer and a dielectric layer on the semiconductor substrate and the gate pattern; removing portions of the dielectric layer to expose the etch stop layer; performing an etch-back process on the etch stop layer to expose the sacrificial gate electrode; removing the sacrificial gate electrode to form a trench; forming a metal layer on the semiconductor substrate including the trench; removing portions of the metal layer to expose the dielectric layer; and performing an etch-back process on the metal layer to a predetermined target.

Abstract: A gate driving unit for a liquid crystal display device including a plurality of liquid crystal pixels, first to Nth gate lines, a plurality of liquid crystal capacitors and a plurality of thin film transistors, includes first and second clock signal lines for providing first and second clock signals; first to Nth shift registers respectively corresponding to the first to Nth gate lines, the first to Nth shift registers receiving one of the first clock signal and the second clock signal and outputting first to Nth scanning signals, respectively; a redundant repair shift register as (N+1)th shift register receiving one of first and second clock signals and outputting a repair scanning signal; a plurality of first switches for respectively connecting one of the first and second clock signal lines to the first to Nth shift registers and the redundant repair shift register; a plurality of second switches for respectively switching a connection of the first to Nth shift registers with the first to Nth gate lines;

Abstract: A driving circuit of a liquid crystal display includes: a timing controller to output a gate control signal and a data control signal to control driving of a gate driving unit and a data driving unit and to output digital video data; a pair of gate driving units to be alternately driven by using at least one frame as a period to supply gate signals to gate lines of a liquid crystal panel in response to the gate control signal; and a data driving unit to supply pixel signals to data lines of the liquid crystal panel in response to the data control signal. Degradation of characteristics of transistors constituting each gate driver can be prevented.

Abstract: Disclosed is a monitoring TEG for an etching process in a semiconductor device. The TEG includes an etch stopping layer on a substrate and a target layer to be etched provided on the etch stopping layer. The target layer to be etched includes a first opening portion formed by etching a portion of the target layer to be etched and a second opening portion formed by etching another portion of the target layer to be etched. The second opening portion has a smaller depth than the first opening portion. A depth of a partial contact hole formed by a first partial etching process may be measured.

Abstract: The invention relates generally to a fuse device of a semiconductor device, and more particularly, to an electrical fuse device of a semiconductor device. Embodiments of the invention provide a fuse device that is capable of reducing programming error caused by non-uniform current densities in a fuse link. In one respect, there is provided an electrical fuse device that includes: an anode; a fuse link coupled to the anode on a first side of the fuse link; a cathode coupled to the fuse link on a second side of the fuse link; a first cathode contact coupled to the cathode; and a first anode contact coupled to the anode, at least one of the first cathode contact and the first anode contact being disposed across a virtual extending surface of the fuse link.

Abstract: A driving circuit of a liquid crystal display includes: a timing controller to output a gate control signal and a data control signal to control driving of a gate driving unit and a data driving unit and to output digital video data; a pair of gate driving units to be alternately driven by using at least one frame as a period to supply gate signals to gate lines of a liquid crystal panel in-response to the gate control signal; and a data driving unit to supply pixel signals to data lines of the liquid crystal panel in response to the data control signal. Degradation of characteristics of transistors constituting each gate driver can be prevented.

Abstract: A test apparatus includes a plurality of pairs of test contacts on a semiconductor substrate; a first test structure which includes a plurality of first test interconnection layers and a first body interconnection layer that is electrically connected to the first test interconnection layers, each of the first test interconnection layers being electrically connected to at least one test contact; and a second test structure which includes a plurality of second test interconnection layers and a second body interconnection layer that is electrically connected to the second test interconnection layers, each of the second test interconnection layers being electrically connected to at least one test contact.

Abstract: A test device, SRAM test device, semiconductor integrated circuit, and methods of fabricating the same are provided. The test device may include a first test active region extending in one direction on a semiconductor substrate, a second test active, apart from the first test active region, extending in one direction on a semiconductor substrate, a plurality of test gate lines crossing the test active regions, a plurality of test contacts on at least one of the test active regions and test gate lines, a plurality of conducting regions electrically connecting the test contacts, and a plurality of conductive wiring lines interconnecting the plurality of test contacts, wherein an open contact chain, which electrically connects the plurality of test contacts, is formed.

Abstract: The invention relates generally to a fuse device of a semiconductor device, and more particularly, to an electrical fuse device of a semiconductor device. Embodiments of the invention provide a fuse device that is capable of reducing programming error caused by non-uniform current densities in a fuse link. In one respect, there is provided an electrical fuse device that includes: an anode; a fuse link coupled to the anode on a first side of the fuse link; a cathode coupled to the fuse link on a second side of the fuse link; a first cathode contact coupled to the cathode; and a first anode contact coupled to the anode, at least one of the first cathode contact and the first anode contact being disposed across a virtual extending surface of the fuse link.

Abstract: The invention relates generally to a fuse device of a semiconductor device, and more particularly, to an electrical fuse device of a semiconductor device. Embodiments of the invention provide a fuse device that is capable of reducing programming error caused by non-uniform current densities in a fuse link. In one respect, there is provided an electrical fuse device that includes: an anode; a fuse link coupled to the anode on a first side of the fuse link; a cathode coupled to the fuse link on a second side of the fuse link; a first cathode contact coupled to the cathode; and a first anode contact coupled to the anode, at least one of the first cathode contact and the first anode contact being disposed across a virtual extending surface of the fuse link.

Abstract: The invention relates generally to a fuse device of a semiconductor device, and more particularly, to an electrical fuse device of a semiconductor device. Embodiments of the invention provide a fuse device that is capable of reducing programming error caused by non-uniform current densities in a fuse link. In one respect, there is provided an electrical fuse device that includes: an anode; a fuse link coupled to the anode on a first side of the fuse link; a cathode coupled to the fuse link on a second side of the fuse link; a first cathode contact coupled to the cathode; and a first anode contact coupled to the anode, at least one of the first cathode contact and the first anode contact being disposed across a virtual extending surface of the fuse link.

Abstract: A method of manufacturing a semiconductor device, the method including providing a semiconductor substrate; forming a gate pattern on the semiconductor substrate such that the gate pattern includes a gate dielectric layer and a sacrificial gate electrode; forming an etch stop layer and a dielectric layer on the semiconductor substrate and the gate pattern; removing portions of the dielectric layer to expose the etch stop layer; performing an etch-back process on the etch stop layer to expose the sacrificial gate electrode; removing the sacrificial gate electrode to form a trench; forming a metal layer on the semiconductor substrate including the trench; removing portions of the metal layer to expose the dielectric layer; and performing an etch-back process on the metal layer to a predetermined target.

Abstract: In a method of forming an insulation layer pattern, an insulation layer is formed on a substrate. An organic layer and a hard mask layer are successively formed on the insulation layer. A preliminary hard mask pattern having first openings is formed by patterning the hard mask layer. A hard mask pattern having the first openings and second openings is formed by patterning the preliminary hard mask pattern. Width control spacers are formed on sidewalls of the first and the second openings. An etching mask pattern is formed by etching the organic layer using the hard mask pattern as an etching mask. The insulation layer pattern having third openings is formed by etching the insulation layer using the etching mask pattern as an etching mask.

Abstract: Provided is a method of fabricating a semiconductor device including a dual silicide process. The method may include sequentially siliciding and stressing a first MOS region, and sequentially siliciding and stressing a second MOS region after siliciding and stressing the first MOS region, the second MOS region being a different type than the first MOS region.

Abstract: A gate drive circuit for a display device is disclosed, by which output states of scan pulses are identically maintained in a manner of minimizing load deviation between connecting units. The present disclosure includes at least two clock transmission lines transmitting at least two clock pulses having a phase difference in-between, a shift register outputting scan pulses sequentially based on the clock pulses transmitted from the clock transmission lines, and a plurality of connecting units connecting the clock transmission lines to the shift register, respectively, wherein at least one of the connecting units is zigzagged in part.

Abstract: A semiconductor substrate includes a first transistor area having a first gate electrode and first source/drain areas, a second transistor area having a second gate electrode and second source/drain areas, and an interface area provided at an interface of the first transistor area and the second transistor area and having a third gate electrode. A first stress film is on the first gate electrode and the first source/drain areas of the first transistor area and at least a portion of the third gate electrode of the interface area. A second stress film is on the second gate electrode and the second source/drain areas of the second transistor area and not overlapping the first stress film on the third gate electrode of the interface area or overlapping at least a portion of the first stress film. The second stress film overlapping at least the portion of the first stress film is thinner than the second stress film in the second transistor area. Related methods are also described.

Abstract: Devices and methods of fabricating a conductive pattern of such devices comprise a non-single crystalline semiconductor pattern formed on a single crystalline semiconductor substrate, an insulating spacer formed on a sidewall of the non-single crystalline semiconductor pattern, the non-single crystalline semiconductor pattern selectively recessed using a cyclic selective epitaxial growth (SEG) process, and a silicide layer formed on the recessed non-single crystalline semiconductor pattern.

Abstract: In a method of forming an insulation layer pattern, an insulation layer is formed on a substrate. An organic layer and a hard mask layer are successively formed on the insulation layer. A preliminary hard mask pattern having first openings is formed by patterning the hard mask layer. A hard mask pattern having the first openings and second openings is formed by patterning the preliminary hard mask pattern. Width control spacers are formed on sidewalls of the first and the second openings. An etching mask pattern is formed by etching the organic layer using the hard mask pattern as an etching mask. The insulation layer pattern having third openings is formed by etching the insulation layer using the etching mask pattern as an etching mask.

Abstract: Methods of forming integrated circuit devices include forming first, second and third gate electrodes on a semiconductor substrate. A first stress film is provided that covers the first gate electrode and at least a first portion of the third gate electrode. The first stress film has a sufficiently high internal stress characteristic to impart a net compressive stress in a first portion of the semiconductor substrate extending opposite the first gate electrode. A second stress film is also provided. The second stress film covers the second gate electrode and at least a second portion of the third gate electrode. The second stress film has a sufficiently high internal stress characteristic to impart a net tensile stress in a second portion of the semiconductor substrate extending opposite the second gate electrode. The second stress film has an upper surface that is coplanar with an upper surface of the first stress film at a location adjacent the third gate electrode.