Abstract: A method for manufacturing a semiconductor device includes forming an insulation layer having a contact hole on a semiconductor substrate. A metal silicide layer is deposited on a surface of the contact hole and the insulation layer to have a concentration gradient that changes from a silicon-rich composition to a metal-rich composition, with the lower portion of the metal silicide layer having the silicon-rich composition and the upper portion of the metal silicide layer having the metal-rich composition. The metal silicide layer is then annealed so that the compositions of metal and silicon in the metal silicide layer become uniform.

Abstract: A metal line of a semiconductor device includes an insulation layer formed on a semiconductor substrate and having a metal line forming region. A diffusion barrier is formed on a surface of the metal line forming region of the insulation layer. The diffusion barrier has a multi-layered structure of a V layer, a VxNy layer and a VxNyOz layer. A metal layer is formed on the diffusion barrier to fill the metal line forming region of the insulation layer.

Abstract: A metal line includes a lower metal line formed on a semiconductor substrate. An insulation layer is formed on the semiconductor substrate having the lower metal line, and a metal line forming region exposing at least a portion of the lower metal line is defined in the insulation layer. A diffusion barrier is formed on a surface of the metal line forming region of the insulation layer and includes a WNx layer, a W—N—B ternary layer, and a Ti—N—B ternary layer. A wetting layer is formed on the diffusion barrier and is made of one of a Ti layer or a TiN layer. An upper metal line is formed on the wetting layer to fill the metal line forming region of the insulation layer.

Abstract: Disclosed is an explosive reactive armor with a momentum transfer mechanism by developing a new protection mechanism in which a momentum transfer mechanism by detonation of a reactive material is integrated with a thickness increase mechanism. In this explosive reactive armor with the momentum transfer mechanism, a flying element always travels with a vertical angle or a slant angle with respect to an ongoing direction of the threat such that a momentum of the flying element is transferred to the threat effectively. As a result of this, shear force is induced over an entire length of the threat and thus the threat can be destroyed. Therefore, a protection effect can always be achieved regardless of an impact angle of the threat. Also, a protection capability can be achieved even in case of a vertical impact which is the most vulnerable case for the existing explosive reactive armor.

Abstract: A multi-layered metal line of a semiconductor device has a lower metal line and an upper metal line. The upper metal line includes a diffusion barrier, which is made of a stack of a first WNx layer, a WCyNx layer and a second WNx layer.

Abstract: A semiconductor memory device is manufactured by: forming a hole by etching an interlayer insulation film formed over a semiconductor substrate; forming a barrier film over the interlayer insulation film including a surface of the hole; forming a first metal film over the barrier film so as to fill in the hole; forming a bit line contact plug in the hole by removing the first metal film and the barrier film so as to expose the interlayer insulation film; carrying out a gas treatment to a surface of the interlayer insulation film including the bit line contact plug so as to promote a growth of metal nucleation; forming a second metal film over the gas treated interlayer insulation film; and forming a bit line in contact with the bit line contact plug by etching the second metal film.

Abstract: A metal suicide layer is fabricated in a semiconductor device. A first metal layer is deposited on a silicon substrate formed with an S interlayer dielectric having a contact hole through PVD. A second metal layer is deposited on the first metal layer through any one of CVD and ALD. Annealing is performed on the silicon substrate which is formed with the first and second metal layers to form the metal silicide. The portions of the second metal layer and the first metal layer which have not reacted during annealing are removed.

Abstract: A metal line in a semiconductor device includes an insulation layer formed on a semiconductor substrate. A metal line forming region is formed in the insulation layer. A metal line is formed to fill the metal line forming region of the insulation layer. And a diffusion barrier that includes an amorphous TaBN layer is formed between the metal line and the insulation layer. The amorphous TaBN layer prevents a copper component from diffusing into the semiconductor substrate, thereby improving upon the characteristics and the reliability of a device.

Abstract: A multi-layered metal line of a semiconductor device and a process of forming the same are described. The multi-layered metal line includes a lower metal line formed on a semiconductor substrate. An insulation layer is subsequently formed on the semiconductor substrate including the lower metal line and has an upper metal line forming region that exposes a portion of the lower metal line. A diffusion barrier formed on a surface of the upper metal line forming region of the insulation layer. The diffusion barrier includes a W—B—N ternary layer. An upper metal line is finally formed on the diffusion barrier to fill the upper metal line forming region of the insulation layer.

Abstract: A metal line of a semiconductor device having a diffusion barrier including CrxBy and a method for forming the same is described. The metal line of a semiconductor device includes an insulation layer formed on a semiconductor substrate. The insulation layer is formed having a metal line forming region. A diffusion barrier including a CrxBy layer is subsequently formed on the surface of the metal line forming region and the insulation layer. A metal line is finally formed to fill the metal line forming region of the insulation layer on the diffusion barrier including a CrxBy layer.

Abstract: A metal line in a semiconductor device includes an insulation layer formed on a semiconductor substrate. A metal line forming region is formed in the insulation layer. A diffusion barrier is formed on a surface of the metal line forming region and a metal line is formed to fill the metal line forming region of the insulation layer. The diffusion barrier is formed between the metal line and the insulation layer. The diffusion barrier has a structure in which a TaSixNy layer is interposed between a first Ta-based layer and a second Ta-based layer. A metal line formed in this manner prevents the contact resistance of the metal line from increasing and the leakage current characteristics from degrading, thereby improving the device characteristics and reliability.

Abstract: A multi-layered metal line of a semiconductor device includes a semiconductor substrate; a lower metal line formed on the semiconductor substrate and recessed on a surface thereof; an insulation layer formed on the semiconductor substrate including the lower metal line and having a damascene pattern for exposing a recessed portion of the lower metal line and for delimiting an upper metal line forming region; a glue layer formed on a surface of the recessed portion of the lower metal line; a first diffusion barrier formed on the glue layer to fill the recessed portion of the lower metal line; a second diffusion barrier formed on the glue layer and the first diffusion barrier; a third diffusion barrier formed on the second diffusion barrier and a surface of the damascene pattern; and an upper metal line formed on the third diffusion barrier to fill the damascene pattern.

Abstract: A multi-layered metal line of a semiconductor device has a lower metal line and an upper metal line. The upper metal line includes a diffusion barrier, which is made of a stack of a first WNx layer, a WCyNx layer and a second WNx layer.

Abstract: A multi-layer metal wiring of a semiconductor device and a method for forming the same are disclosed. The multi-layer metal wiring of the semiconductor device includes a lower Cu wiring, and an upper Al wiring formed to be contacted with the lower Cu wiring, and a diffusion barrier layer interposed between the lower Cu wiring and the upper Al wiring. The diffusion barrier layer is formed of a W-based layer.

Abstract: A metal wiring of a semiconductor device includes a semiconductor substrate; an insulating layer provided with a damascene pattern formed over the semiconductor substrate; a diffusion barrier layer which contains a RuO2 layer formed on a surface of the damascene pattern and an Al deposit-inhibiting layer formed on a portion of the RuO2 layer in both-side upper portion of the damascene pattern; and a wiring metal layer including Al formed on the diffusion barrier layer by MOCVD method in order to fill the damascene pattern.

Abstract: A semiconductor memory device is manufactured by: forming a hole by etching an interlayer insulation film formed over a semiconductor substrate; forming a barrier film over the interlayer insulation film including a surface of the hole; forming a first metal film over the barrier film so as to fill in the hole; forming a bit line contact plug in the hole by removing the first metal film and the barrier film so as to expose the interlayer insulation film; carrying out a gas treatment to a surface of the interlayer insulation film including the bit line contact plug so as to promote a growth of metal nucreation; forming a second metal film over the gas treated interlayer insulation film; and forming a bit line in contact with the bit line contact plug by etching the second metal film.

Abstract: Methods of forming metal nitride layers on a substrate include reacting a metal source gas with a nitrogen source gas in a process chamber to form a metal nitride layer on the substrate. The process chamber may have an atmosphere having a pressure of about 0.1 mTorr to about 5 mTorr and a temperature of about 200° C. to about 450° C. A ratio of the flow rate of the metal source gas to the flow rate of the nitrogen source gas may be “1” or more. An interlayer insulating layer may be formed on the semiconductor substrate prior to formation of the metal nitride layer.

Abstract: In a multi-media system for transferring and receiving a transport stream (MPEG2-TS) between a receiver and a recording/reproducing device using the IEEE 1394 interface, a program number command of a selected program is transferred from the receiver to the recording/reproducing device during a recording/playback mode, and the recording and playback are controlled by only one input device for the receiver. Therefore, other devices of the multi-media system can be controlled without extra hardware added to the receiver. Further, an on-screen graphic (OSG) is provided by the receiver, resulting in a consistent OSG.

Abstract: A stereophonic sound reproduction system for compensating a low frequency signal and a method thereof, wherein a mono component signal for compensating low frequency signals which are attenuated when removing a crosstalk of inputted left and right signals inputted is calculated using an average value between the left and right signals, left and right compensation gains which are inversely proportional to an absolute value of a power difference value between the first left and right signals, an amplitude of the calculated mono component signal is controlled according to the left and right compensation gains, and thereafter the mono component signal with the controlled amplitude is added to the left and right signals when removing the crosstalk, whereby the left and right signals from which the crosstalk is removed and to which the mono component signal is added are outputted through left and right speakers to thus prevent distortion of the low frequency signals of original stereophonic sound with maintaining a

Abstract: Methods of forming metal nitride layers on a substrate include reacting a metal source gas with a nitrogen source gas in a process chamber to form a metal nitride layer on the substrate. The process chamber may have an atmosphere having a pressure of about 0.1 mTorr to about 5 mTorr and a temperature of about 200° C. to about 450° C. A ratio of the flow rate of the metal source gas to the flow rate of the nitrogen source gas may be “1” or more. An interlayer insulating layer may be formed on the semiconductor substrate prior to formation of the metal nitride layer.