Abstract: The methods and structures described are used to prevent protrusion of contact metal (such as W) horizontally into gate stacks of neighboring devices to affect the work functions of these neighboring devices. The metal gate under contact plugs that are adjacent to devices and share the (or are connected to) metal gate is defined and lined with a work function layer that has good step coverage to prevent contact metal from extruding into gate stacks of neighboring devices. Only modification to the mask layout for the photomask(s) used for removing dummy polysilicon is involved. No additional lithographical operation or mask is needed. Therefore, no modification to the manufacturing processes or additional substrate processing steps (or operations) is involved or required. The benefits of using the methods and structures described above may include increased device yield and performance.

Abstract: The present disclosure provides a semiconductor device having a transistor. The transistor includes a substrate. The transistor includes a collector region that is formed in a portion of the substrate. The transistor includes a base region that is surrounded by the collector region. The transistor includes an emitter region that is surrounded by the based region. The transistor includes an isolation structure that is disposed adjacent the emitter region. The transistor includes a gate structure that is disposed over a portion of the emitter region and a portion of the isolation structure.

Abstract: An exemplary structure for a field effect transistor according to at least one embodiment comprises a substrate comprising a surface; a gate structure comprising sidewalls and a top surface over the substrate; a spacer adjacent to the sidewalls of the gate structure; a first contact etch stop layer over the spacer and extending along the surface of the substrate; an interlayer dielectric layer adjacent to the first contact etch stop layer, wherein a top surface of the interlayer dielectric layer is coplanar with the top surface of the gate structure; and a second contact etch stop layer over the top surface of the gate structure.

Abstract: The present disclosure provides a method that includes forming a high k dielectric layer on a semiconductor substrate; forming a polysilicon layer on the high k dielectric layer; patterning the high k dielectric layer and polysilicon layer to form first and second dummy gates in first and second field effect transistor (FET) regions, respectively; forming an inter-level dielectric (ILD); applying a first CMP process to the semiconductor substrate, exposing the first and second dummy gates; removing the polysilicon from the first dummy gate, resulting in a first gate trench; forming a first metal electrode in the first gate trench; applying a second CMP process; forming a mask covering the first FET region and exposing the second dummy gate; thereafter removing the polysilicon from the second dummy gate, resulting in a second gate trench; forming a second metal electrode in the second gate trench; and applying a third CMP process.

Abstract: The applications discloses a semiconductor device comprising a substrate having a first active region, a second active region, and an isolation region having a first width interposed between the first and second active regions; a P-metal gate electrode over the first active region and extending over at least ? of the first width of the isolation region; and an N-metal gate electrode over the second active region and extending over no more than ? of the first width. The N-metal gate electrode is electrically connected to the P-metal gate electrode over the isolation region.

Abstract: This description relates to a method for fabricating an interconnection structure in a complementary metal-oxide-semiconductor (CMOS). The method includes forming a first opening in a dielectric layer over a substrate and partially filling the first opening with a second work-function metal layer, wherein a top surface of the second work-function metal layer is below a top surface of the first opening. The method further includes forming a second opening adjoining the first opening in the dielectric layer over the substrate and depositing a first work-function metal layer in the first and second openings, whereby the first work-function metal layer is over the second work-function metal layer in the first opening. The method further includes depositing a signal metal layer over the first work-function metal layer in the first and second openings and planarizing the signal metal layer.

Abstract: A method of fabricating a laterally diffused metal oxide semiconductor (LDMOS) transistor includes forming a dummy gate over a substrate. A source and a drain are formed over the substrate on opposite sides of the dummy gate. A first silicide is formed on the source. A second silicide is formed on the drain so that an unsilicided region of at least one of the drain or the source is adjacent to the dummy gate. The unsilicided region of the drain provides a resistive region capable of sustaining a voltage load suitable for a high voltage LDMOS application. A replacement gate process is performed on the dummy gate to form a gate.

Abstract: A method of forming a device is presented. The method includes providing a structure having first and second regions. A diffusion barrier is formed between at least a portion of the first and second regions. The diffusion barrier comprises cavities that reduce diffusion of elements between the first and second regions.

Abstract: A method includes forming a first isolation feature of a first width and a second isolation feature of a second width in a substrate, the first width being substantially greater than the second width; forming an implantation mask on the substrate, wherein the implantation mask covers the first isolation feature and exposes the second isolation feature; performing an ion implantation process to the substrate using the implantation mask; and thereafter performing an etching process to the substrate.

Abstract: An embodiment of the disclosure includes a method of forming an integrated circuit. A substrate having an active region and a passive region is provided. A plurality of trenches is formed in the passive region. A root mean square of a length and a width of each trench is less than 5 ?m. An isolation material is deposited over the substrate to fill the plurality of trenches. The isolation material is planarized to form a plurality of isolation structures. A plurality of silicon gate stacks and at least one silicon resistor stack are formed on the substrate in the active region and on the plurality of isolation structures respectively.

Abstract: The disclosure relates to spacer structures of a semiconductor device. An exemplary structure for a semiconductor device comprises a substrate having a first active region and a second active region; a plurality of first gate electrodes having a gate pitch over the first active region, wherein each first gate electrode has a first width; a plurality of first spacers adjoining the plurality of first gate electrodes, wherein each first spacer has a third width; a plurality of second gate electrodes having the same gate pitch as the plurality of first gate electrodes over the second active region, wherein each second gate electrode has a second width greater than the first width; and a plurality of second spacers adjoining the plurality of second gate electrodes, wherein each second spacer has a fourth width less than the third width.

Abstract: The present disclosure provides a semiconductor device having a transistor. The transistor includes a substrate and first and second wells that are disposed within the substrate. The first and second wells are doped with different types of dopants. The transistor includes a first gate that is disposed at least partially over the first well. The transistor further includes a second gate that is disposed over the second well. The transistor also includes source and drain regions. The source and drain regions are disposed in the first and second wells, respectively. The source and drain regions are doped with dopants of a same type.

Abstract: The disclosure relates to integrated circuit fabrication, and more particularly to an interconnection structure for N/P metal gates. An exemplary structure for an interconnection structure comprises a first gate electrode having a first portion of a first work-function metal layer under a first portion of a signal metal layer; and a second gate electrode having a second portion of the first work-function metal layer interposed between a second work-function metal layer and a second portion of the signal metal layer, wherein the second portion of the signal metal layer is over the second portion of the first work-function metal layer, wherein the second portion of the signal metal layer and the first portion of the signal metal layer are continuous, and wherein a maximum thickness of the second portion of the signal metal layer is less than a maximum thickness of the first portion of the signal metal layer.

Abstract: A hybrid orientation substrate includes a base substrate having a first orientation, a first surface layer having a first orientation disposed on the base substrate in a first region, and a second surface layer disposed on the base substrate in a second region. The second surface layer has an upper sub-layer having a second orientation, and a lower sub-layer between the base substrate and the upper sub-layer. The lower sub-layer having a first stress induces a second stress on the upper sub-layer.

Abstract: An offset gate semiconductor device includes a substrate and an isolation feature formed in the substrate. An active region is formed in the substrate substantially adjacent to the isolation feature. An interface layer is formed on the substrate over the isolation feature and the active region. A polysilicon layer is formed on the interface layer over the isolation feature and the active region. A trench being formed in the polysilicon layer over the isolation feature. The trench extending to the interface layer. A fill layer is formed to line the trench and a metal gate formed in the trench.

Abstract: A method of manufacture of an integrated circuit system includes: providing a second layer between a first layer and a third layer; forming an active device over the third layer; forming the third layer to form an island region underneath the active device; forming the second layer to form a floating second layer with an undercut beneath the island region; and depositing a fourth layer around the island region and the floating second layer.

Abstract: A semiconductor method includes providing a silicon semiconductor substrate. A gate and a plurality of source/drain regions are formed on the silicon semiconductor substrate to form at least one pFET. A silicon-germanium layer is formed over the plurality of source/drain regions. The germanium is condensed from the silicon-germanium layer to form a plurality of source/drains in the plurality of source/drain regions by forming an oxide layer over the silicon-germanium layer. An interlevel dielectric layer is formed over the gate and the source/drain regions. A plurality of contacts is formed in the interlevel dielectric layer to the gate and the plurality of source/drain regions.

Abstract: The invention relates to integrated circuit fabrication, and more particularly to a metal gate structure. An exemplary structure for a CMOS semiconductor device comprises a substrate comprising a P-active region, an N-active region, and an isolation region interposed between the P- and N-active regions; a P-metal gate electrode over the P-active region, that extends over the isolation region; and an N-metal gate electrode having a first width over the N-active region, that extends over the isolation region and has a contact section in the isolation region electrically contacting the P-metal gate electrode, wherein the contact section has a second width greater than the first width.

Abstract: The disclosure relates to integrated circuit fabrication, and more particularly to a method for fabricating a semiconductor device. An exemplary method for fabricating the semiconductor device comprises providing a substrate; forming pad oxide layers over a frontside and a backside of the substrate; forming hardmask layers over the pad oxide layers on the frontside and the backside of the substrate; and thinning the hardmask layer over the pad oxide layer on the frontside of the substrate.

Abstract: The applications discloses a semiconductor device comprising a substrate having a first active region, a second active region, and an isolation region having a first width interposed between the first and second active regions; a P-metal gate electrode over the first active region and extending over at least ? of the first width of the isolation region; and an N-metal gate electrode over the second active region and extending over no more than ? of the first width. The N-metal gate electrode is electrically connected to the P-metal gate electrode over the isolation region.