Abstract: A vertical slit transistor includes raised source, drain, and channel regions in a semiconductor substrate. Two gate electrodes are positioned adjacent respective sidewalls of the semiconductor substrate. A dielectric material separates the gate electrodes from the source and drain regions.

Abstract: A high performance GAA FET is described in which vertically stacked silicon nanowires carry substantially the same drive current as the fin in a conventional FinFET transistor, but at a lower operating voltage, and with greater reliability. One problem that occurs in existing nanowire GAA FETs is that, when a metal is used to form the wrap-around gate, a short circuit can develop between the source and drain regions and the metal gate portion that underlies the channel. The vertically stacked nanowire device described herein, however, avoids such short circuits by forming insulating barriers in contact with the source and drain regions, prior to forming the gate. Through the use of sacrificial films, the fabrication process is almost fully self-aligned, such that only one lithography mask layer is needed, which significantly reduces manufacturing costs.

Abstract: Fabricating a semiconductor device includes providing a strained semiconductor material (SSM) layer disposed on a dielectric layer, forming a first plurality of fins on the SSOI structure, at least one fin of the first plurality of fins is in a nFET region and at least one fin is in a pFET region, etching portions of the dielectric layer under portions of the SSM layer of the at least one fin in the pFET region, filling areas cleared by the etching, forming a second plurality of fins from the at least one fin in the nFET region such that each fin comprises a portion of the SSM layer disposed on the dielectric layer, and forming a third plurality of fins from the at least one fin in the pFET region such that each fin comprises a portion of the SSM layer disposed on a flowable oxide.

Abstract: One illustrative method disclosed herein includes removing the sidewall spacers and a gate cap layer so as to thereby expose an upper surface and sidewalls of a sacrificial gate structure, forming an etch stop layer above source/drain regions of a device and on the sidewalls and upper surface of the sacrificial gate structure, forming a first layer of insulating material above the etch stop layer, removing the sacrificial gate structure so as to define a replacement gate cavity that is laterally defined by portions of the etch stop layer, forming a replacement gate structure in the replacement gate cavity, and forming a second gate cap layer above the replacement gate structure.

Abstract: One illustrative method disclosed herein includes, among other things, forming a fin having an upper surface and a plurality of side surfaces, forming a sacrificial gate structure comprised of a low-density oxide material having a density of less than 1.8 g/cm3 on and in contact with the upper surface and the side surfaces of the fin and a sacrificial gate material positioned on and in contact with the upper surface of the low-density oxide material, and forming a sidewall spacer adjacent the sacrificial gate structure. The method further includes removing the sacrificial gate material so as to thereby expose the low-density oxide material, so as to define a replacement gate cavity, and forming a replacement gate structure in the replacement gate cavity.

Abstract: One method disclosed includes, among other things, forming an overall fin structure having a stepped cross-sectional profile, the fin structure having an upper part and a lower part positioned under the upper part, wherein the upper part has a first width and the lower part has a second width that is less than the first width, forming a layer of insulating material in trenches adjacent the overall fin structure such that the upper part of the overall fin structure and a portion of the lower part of the overall fin structure are exposed above an upper surface of the layer of insulating material, and forming a gate structure around the exposed upper part of the overall fin structure and the exposed portion of the lower part of the overall fin structure.

Abstract: A large area electrical contact for use in integrated circuits features a non-planar, sloped bottom profile. The sloped bottom profile provides a larger electrical contact area, thus reducing the contact resistance, while maintaining a small contact footprint. The sloped bottom profile can be formed by recessing an underlying layer, wherein the bottom profile can be crafted to have a V-shape, U-shape, crescent shape, or other profile shape that includes at least a substantially sloped portion in the vertical direction. In one embodiment, the underlying layer is an epitaxial fin of a FinFET. A method of fabricating the low-resistance electrical contact employs a thin etch stop liner for use as a hard mask. The etch stop liner, e.g., HfO2, prevents erosion of an adjacent gate structure during the formation of the contact.

Abstract: Techniques and structures for controlling etch-back of a finFET fin are described. One or more layers may be deposited over the fin and etched. Etch-back of a planarization layer may be used to determine a self-limited etch height of one or more layers adjacent the fin and a self-limited etch height of the fin. Strain-inducing material may be formed at regions of the etched fin to induce strain in the channel of a finFET.

Abstract: A FinFET device includes a substrate, a gate structure positioned above the substrate, and sidewall spacers positioned adjacent to the gate structure. An epi semiconductor material is positioned in source and drain regions of the FinFET device and laterally outside of the sidewall spacers. A fin extends laterally under the gate structure and the sidewall spacers in a gate length direction of the FinFET device, wherein the end surfaces of the fin abut and engage the epi semiconductor material. A stressed material is positioned in a channel cavity located below the fin, above the substrate, and laterally between the epi semiconductor material, the stressed material having a top surface that abuts and engages a bottom surface of the fin, a bottom surface that abuts and engages the substrate, and end surfaces that abut and engage the epi semiconductor material.

Abstract: A method for making a semiconductor device is provided. Raised source and drain regions are formed with a tensile strain-inducing material, after thermal treatment to form source drain extension regions, to thereby preserve the strain-inducing material in desired substitutional states.

Abstract: A technique relates to fabricating a macro for measurements utilized in dual spacer, dual epitaxial transistor devices. The macro is fabricated according to a fabrication process. The macro is a test layout of a semiconductor structure having n-p bumps at junctions between NFET areas and PFET areas. Optical critical dimension (OCD) spectroscopy is performed to obtain the measurements of the n-p bumps on the macro. An amount of chemical mechanical polishing is determined to remove the n-p bumps on the macro based on the measurements of the n-p bumps on the macro. Chemical mechanical polishing is performed to remove the n-p bumps on the macro. The amount previously determined for the macro is utilized to perform chemical mechanical polishing for each of the dual spacer, dual epitaxial layer transistor devices having been fabricated under the fabrication process of the macro in which the fabrication process produced the n-p bumps.

Abstract: A method for making a semiconductor device includes forming laterally spaced-apart semiconductor fins above a substrate. At least one dielectric layer is formed adjacent an end portion of the semiconductor fins and within the space between adjacent semiconductor fins. A pair of sidewall spacers is formed adjacent outermost semiconductor fins at the end portion of the semiconductor fins. The at least one dielectric layer and end portion of the semiconductor fins between the pair of sidewall spacers are removed. Source/drain regions are formed between the pair of sidewall spacers.

Abstract: An integrated circuit transistor is formed on a substrate. A trench in the substrate is at least partially filled with a metal material to form a source (or drain) contact buried in the substrate. The substrate further includes a source (or drain) region in the substrate which is in electrical connection with the source (or drain) contact. The substrate further includes a channel region adjacent to the source (or drain) region. A gate dielectric is provided on top of the channel region and a gate electrode is provided on top of the gate dielectric. The substrate may be of the silicon on insulator (SOI) or bulk type. The buried source (or drain) contact makes electrical connection to a side of the source (or drain) region using a junction provided at a same level of the substrate as the source (or drain) and channel regions.

Abstract: A technique relates to fabricating a macro for measurements utilized in dual spacer, dual epitaxial transistor devices. The macro is fabricated according to a fabrication process. The macro is a test layout of a semiconductor structure having n-p bumps at junctions between NFET areas and PFET areas. Optical critical dimension (OCD) spectroscopy is performed to obtain the measurements of the n-p bumps on the macro. An amount of chemical mechanical polishing is determined to remove the n-p bumps on the macro based on the measurements of the n-p bumps on the macro. Chemical mechanical polishing is performed to remove the n-p bumps on the macro. The amount previously determined for the macro is utilized to perform chemical mechanical polishing for each of the dual spacer, dual epitaxial layer transistor devices having been fabricated under the fabrication process of the macro in which the fabrication process produced the n-p bumps.

Abstract: Fabricating a semiconductor device includes providing a strained semiconductor material (SSM) layer disposed on a dielectric layer, forming a first plurality of fins on the SSOI structure, at least one fin of the first plurality of fins is in a nFET region and at least one fin is in a pFET region, etching portions of the dielectric layer under portions of the SSM layer of the at least one fin in the pFET region, filling areas cleared by the etching, forming a second plurality of fins from the at least one fin in the nFET region such that each fin comprises a portion of the SSM layer disposed on the dielectric layer, and forming a third plurality of fins from the at least one fin in the pFET region such that each fin comprises a portion of the SSM layer disposed on a flowable oxide.

Abstract: A method of forming a semiconductor device that includes forming a plurality of semiconductor pillars. A dielectric spacer is formed between at least one set of adjacent semiconductor pillars. Semiconductor material is epitaxially formed on sidewalls of the adjacent semiconductor pillars, wherein the dielectric spacer obstructs a first portion of epitaxial semiconductor material formed on a first semiconductor pillar from merging with a second portion of epitaxial semiconductor material formed on a second semiconductor pillar.

Abstract: Embodiments of the present invention may include methods of incorporating an embedded etch barrier layer into the replacement metal gate layer of field effect transistors (FETs) having replacement metal gates, as well as the structure formed thereby. The embedded etch stop layer may be composed of embedded dopant atoms and may be formed using ion implantation. The embedded etch stop layer may make the removal of replacement metal gate layers easier and more controllable, providing horizontal surfaces and determined depths to serve as the base for gate cap formation. The gate cap may insulate the gate from adjacent self-aligned electrical contacts.

Abstract: An MIS contact structure comprises a layer of semiconductor material, a layer of insulating material having a contact opening formed therein, a layer of contact insulating material having substantially vertically oriented portions and a substantially horizontally oriented portion, the vertically oriented portions of the layer of contact insulating material contacting a portion, but not all, of the sidewalls of the contact opening and the horizontally oriented portion of the layer of contact insulating material contacting the semiconductor layer. A conductive material is positioned on the layer of contact insulating material within the contact opening, the conductive material layer having vertically oriented portions and a horizontally oriented portion and a conductive contact positioned in the contact opening that contacts the uppermost surfaces of the conductive material layer and the layer of contact insulating material.

Abstract: A semiconductor substrate includes a bulk substrate layer that extends along a first axis to define a width and a second axis perpendicular to the first axis to define a height. A plurality of hetero semiconductor fins includes an epitaxial material formed on a first region of the bulk substrate layer. A plurality of non-hetero semiconductor fins is formed on a second region of the bulk substrate layer different from the first region. The non-hetero semiconductor fins are integrally formed from the bulk substrate layer such that the material of the non-hetero semiconductor fins is different from the epitaxial material.

Abstract: In forming a finFET, a selective nitridation process is used during spacer formation on the gate to support a finer fin pitch than could be achieved using traditional spacer deposition processes. The spacer formation may also allow precise control over formation of source and drain junctions.