Abstract: A semiconductor device includes an active region. A gate electrode is disposed on the active region. An isolation region adjoins the active region, and is recessed with respect to a top surface of the active region underlying the gate electrode. The isolation region may be recessed a depth substantially equal to a height of the gate electrode. In some embodiments, the gate electrode is configured to support current flow through the active region along a first direction, and a tensile stress layer covers the gate electrode and is configured to apply a tensile stress to the gate electrode along a second direction perpendicular to the first direction. The tensile stress layer may cover the recessed isolation region and portions of the active region between the isolation region and the gate electrode. In further embodiments, an interlayer insulating film is disposed on the tensile stress layer and is configured to apply a tensile stress to the gate electrode along the second direction.

Abstract: Methods of manufacturing a semiconductor device include forming an NMOS transistor on a semiconductor substrate, forming a first interlayer dielectric layer on the NMOS transistor, and dehydrogenating the first interlayer dielectric layer. Dehydrogenating the first interlayer dielectric layer may change a stress of the first interlayer dielectric layer. In particular, the first interlayer dielectric layer may have a tensile stress of 200 MPa or more after dehydrogenization. Semiconductor devices including dehydrogenated interlayer dielectric layers are also provided.

Abstract: The present invention provides, in one embodiment, a method of manufacturing a metal oxide semiconductor (MOS) transistor (100). The method comprises forming an active area (105) in a substrate (115), wherein the active area (105) is bounded by an isolation structure (120). The method further includes placing at least one stress adjuster (130) adjacent the active area (105), wherein the stress adjuster (130) is positioned to modify a mobility of a majority carrier within a channel region (155) of the MOS transistor (100). Other embodiments of the present invention include a MOS transistor device (200) and a process (300) for constructing an integrated circuit.

Abstract: A method of forming wires of a semiconductor device including forming a first metal wire on a semiconductor substrate; forming a first insulating film on the first metal wire; etching a portion of the first insulating film to expose a surface portion of the first metal wire; forming a first barrier metal film on sidewalls of the opening and the exposed first metal wire; etching a portion of the first barrier metal film on the first metal wire to expose a surface portion of the first metal wire; performing a heat treatment process on the exposed surface portion of the first metal wire to improve surface roughness; and forming a second wire by filling the opening using a conductive material.

Abstract: The present invention provides, in one embodiment, a method of manufacturing a metal oxide semiconductor (MOS) transistor (100). The method comprises forming an active area (105) in a substrate (115), wherein the active area (105) is bounded by an isolation structure (120). The method further includes placing at least one stress adjuster (130) adjacent the active area (105), wherein the stress adjuster (130) is positioned to modify a mobility of a majority carrier within a channel region (155) of the MOS transistor (100). Other embodiments of the present invention include a MOS transistor device (200) and a process (300 ) for constructing an integrated circuit.

Abstract: A trench is formed in a low K dielectric (100) over a plurality of vias (120) also formed in the low K dielectric layer (100). The vias are separated by a distance of less than XV and the edge of the trench is greater than XTO from the edge ? of the via closest to the edge of the trench. The trench and vias are subsequently filled with copper (150, 160) to form the interconnect line.

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 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 metal interconnection of a semiconductor device, formed using a damascene process, has large grains and yet a smooth surface. First, a barrier layer and a metal layer are sequentially formed in an opening in an interlayer dielectric layer. A CMP process is carried out on the metal layer to form a metal interconnection remaining within the opening. Then, the metal interconnection is treated with plasma. The plasma treatment creates compressive stress in the metal interconnection, which stress produces hillocks at the surface of the metal interconnection. In addition, the plasma treatment process causes grains of the metal to grow, especially when the design rule is small, to thereby decrease the resistivity of the metal interconnection. The hillocks are then removed by a CMP process aimed at polishing the portion of the barrier layer that extends over the upper surface of the interlayer dielectric layer. Finally, a capping insulating layer is formed.

Abstract: A semiconductor device is provided. A unit wiring level of the semiconductor device includes; first and second wiring layers spaced apart from each other on a support layer, a large space formed adjacent to the first wiring layer and including a first air gap of predetermined width as measured from a sidewall of the first wiring layer, and a portion of a thermally degradable material layer formed on the support layer, small space formed between the first and second wiring layers, wherein the small space is smaller than the large space, and a second air gap at least partially fills the small space, and a porous insulating layer formed on the first and second air gaps.

Abstract: A trench is formed in a low K dielectric (100) over a plurality of vias (120) also formed in the low K dielectric layer (100). The vias are separated by a distance of less than XV and the edge of the trench is greater than XTO from the edge ? of the via closest to the edge of the trench. The trench and vias are subsequently filled with copper (150), (160) to form the interconnect line.

Abstract: A semiconductor device includes an active region. A gate electrode is disposed on the active region. An isolation region adjoins the active region, and is recessed with respect to a top surface of the active region underlying the gate electrode. The isolation region may be recessed a depth substantially equal to a height of the gate electrode. In some embodiments, the gate electrode is configured to support current flow through the active region along a first direction, and a tensile stress layer covers the gate electrode and is configured to apply a tensile stress to the gate electrode along a second direction perpendicular to the first direction. The tensile stress layer may cover the recessed isolation region and portions of the active region between the isolation region and the gate electrode. In further embodiments, an interlayer insulating film is disposed on the tensile stress layer and is configured to apply a tensile stress to the gate electrode along the second direction.

Abstract: A method of forming wires of a semiconductor device including forming a first metal wire on a semiconductor substrate; forming a first insulating film on the first metal wire; etching a portion of the first insulating film to expose a surface portion of the first metal wire; forming a first barrier metal film on sidewalls of the opening and the exposed first metal wire; etching a portion of the first barrier metal film on the first metal wire to expose a surface portion of the first metal wire; performing a heat treatment process on the exposed surface portion of the first metal wire to improve surface roughness; and forming a second wire by filling the opening using a conductive material.

Abstract: Methods of manufacturing a semiconductor device include forming an NMOS transistor on a semiconductor substrate, forming a first interlayer dielectric layer on the NMOS transistor, and dehydrogenating the first interlayer dielectric layer. Dehydrogenating the first interlayer dielectric layer may change a stress of the first interlayer dielectric layer. In particular, the first interlayer dielectric layer may have a tensile stress of 200 MPa or more after dehydrogenization. Semiconductor devices including dehydrogenated interlayer dielectric layers are also provided.

Abstract: A metal interconnection of a semiconductor device, formed using a damascene process, has large grains and yet a smooth surface. First, a barrier layer and a metal layer are sequentially formed in an opening in an interlayer dielectric layer. A CMP process is carried out on the metal layer to form a metal interconnection remaining within the opening. Then, the metal interconnection is treated with plasma. The plasma treatment creates compressive stress in the metal interconnection, which stress produces hillocks at the surface of the metal interconnection. In addition, the plasma treatment process causes grains of the metal to grow, especially when the design rule is small, to thereby decrease the resistivity of the metal interconnection. The hillocks are then removed by a CMP process aimed at polishing the portion of the barrier layer that extends over the upper surface of the interlayer dielectric layer. Finally, a capping insulating layer is formed.

Abstract: Isolated metal structures (110), (140) are formed adjacent to terminated metal lines (100), (130) that are connect by a via (120). The isolated structures (110), (140) act to suppress the stress created in the terminated metal lines (100), (130) during thermal cycling.

Abstract: A method of CMP polishing of a semiconductor wafer is described that includes using a polishing pad on a platen/table with the polishing pad including a sub-pad containing pockets of magnetorheological fluid. The stiffness of the sub-pad is controlled by selectively applying a magnetic field at selective pockets containing magnetorheological fluid to change the viscosity of the magnetorheological fluid. The changing stiffness increases the polishing rate of the pad in the areas of the magnetic field.