Abstract: A method for forming an integrated circuit having a test macro using a multiple patterning lithography process (MPLP) is provided. The method includes forming an active area of the test macro having a first and second gate region during a first step of MPLP, and forming a first and second source/drain regions in the active area during a second step of the MPLP. The method also includes forming a first contact connected to the first gate region, a second contact connected to the second gate region, a third contact connected to the first source/drain region, and a forth contact connected to the source/drain region and determining if an overlay shift occurred between the first step and the second step of the step of the MPLP by testing for a short between one or more of the first contact, the second contact, the third contact, or the fourth contact.

Abstract: After formation of a gate structure and a gate spacer, portions of an insulator layer underlying a semiconductor fin are etched to physically expose semiconductor surfaces of an underlying semiconductor material layer from underneath a source region and a drain region. Each of the extended source region and the extended drain region includes an anchored single crystalline semiconductor material portion that is in epitaxial alignment to the single crystalline semiconductor structure of the underlying semiconductor material layer and laterally applying a stress to the semiconductor fin. Because each anchored single crystalline semiconductor material portion is in epitaxial alignment with the underlying semiconductor material layer, the channel of the fin field effect transistor is effectively stressed along the lengthwise direction of the semiconductor fin.

Abstract: A metal layer is deposited over a material layer. The metal layer includes an elemental metal that can be converted into a dielectric metal-containing compound by plasma oxidation or nitridation. A hard mask portion is formed over the metal layer. A plasma impermeable spacer is formed on at least one first sidewall of the hard mask portion, while at least one second sidewall of the hard mask portion is physically exposed. Plasma oxidation or nitridation is performed to convert physically exposed surfaces of the metal layer into the dielectric metal-containing compound. A sequence of a surface pull back of the hard mask portion, cavity etching, another surface pull back, and conversion of top surfaces into the dielectric metal-containing compound are repeated to form a hole pattern having a spacing that is not limited by lithographic minimum dimensions.

Abstract: In one embodiment, a semiconductor device is provided that includes a gate structure present on a channel portion of a fin structure. The gate structure includes a dielectric spacer contacting a sidewall of a gate dielectric and a gate conductor. Epitaxial source and drain regions are present on opposing sidewalls of the fin structure, wherein surfaces of the epitaxial source region and the epitaxial drain region that is in contact with the sidewalls of the fin structure are aligned with an outside surface of the dielectric spacer. In some embodiments, the dielectric spacer, the gate dielectric, and the gate conductor of the semiconductor device are formed using a single photoresist mask replacement gate sequence.

Abstract: A method for fabricating a finfet with a buried local interconnect and the resulting device are disclosed. Embodiments include forming a silicon fin on a BOX layer, forming a gate electrode perpendicular to the silicon fin over a portion of the silicon fin, forming a spacer on each of opposite sides of the gate electrode, forming source/drain regions on the silicon fin at opposite sides of the gate electrode, recessing the BOX layer, undercutting the silicon fin and source/drain regions, at opposite sides of the gate electrode, and forming a local interconnect on a recessed portion of the BOX layer.

Abstract: Self-aligned contacts of a semiconductor device are fabricated by forming a metal gate structure on a portion of a semiconductor layer of a substrate. The metal gate structure contacts inner sidewalls of a gate spacer. A second sacrificial epitaxial layer is formed on a first sacrificial epitaxial layer. The first sacrificial epitaxial layer is adjacent to the gate spacer and is formed on source/drain regions of the semiconductor layer. The first and second sacrificial epitaxial layers are recessed. The recessing exposes at least a portion of the source/drain regions. A first dielectric layer is formed on the exposed portions of the source/drain regions, and over the gate spacer and metal gate structure. At least one cavity within the first dielectric layer is formed above at least one of the exposed portions of source/drain regions. At least one metal contact is formed within the at least one cavity.

Abstract: Transistors including one or more semiconductor fins formed on a substrate. The one or more semiconductor fins are thinner in a channel region than in source and drain regions and have rounded corners formed by an anneal in a gaseous environment. A gate dielectric layer is on the channel region of the one or more semiconductor fins, conforming to the contours of the one or more semiconductor fins. A gate structure is on the gate dielectric layer.

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 wraparound 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: A method for making a semiconductor device includes forming laterally spaced-apart semiconductor fins above a substrate, and a gate overlying the semiconductor fins. The gate has a tapered outer surface. A first pair of sidewall spacers is formed adjacent the gate an exposed tapered outer surface is also defined. Portions of the gate are removed at the exposed tapered outer surface to define a recess. A second pair of sidewall spacers is formed covering the first pair of sidewall spacers and the recess. Source/drain regions are formed on the semiconductor fins.

Abstract: Dummy gates are removed from a pre-metal layer to produce a first opening (with a first length) and a second opening (with a second length longer than the first length). Work function metal for a metal gate electrode is provided in the first and second openings. Tungsten is deposited to fill the first opening and conformally line the second opening, thus leaving a third opening. The thickness of the tungsten layer substantially equals the length of the first opening. The third opening is filled with an insulating material. The tungsten is then recessed in both the first and second openings using a dry etch to substantially a same depth from a top surface of the pre-metal layer to complete the metal gate electrode. Openings left following the recess operation are then filled with a dielectric material forming a cap on the gate stack which includes the metal gate electrode.

Abstract: Embodiments are directed to a method of forming a leakage current stopper of a fin-type field effect transistor (FinFET). The method includes forming at least one fin having an active region, a non-active region and a channel region in the active region. The method further includes exposing a surface of the non-active region, wherein the exposed surface leads to a portion of the non-active region that is substantially underneath the channel region. The method further includes implanting dopants through the exposed surface of the non-active region to form the leakage current stopper region.

Abstract: A method for making a semiconductor device may include forming, above a substrate, first and second semiconductor regions laterally adjacent one another and each including a first semiconductor material. The first semiconductor region may have a greater vertical thickness than the second semiconductor region and define a sidewall with the second semiconductor region. The method may further include forming a spacer above the second semiconductor region and adjacent the sidewall, and forming a third semiconductor region above the second semiconductor region and adjacent the spacer, with the second semiconductor region including a second semiconductor material different than the first semiconductor material. The method may also include removing the spacer and portions of the first semiconductor material beneath the spacer, forming a first set of fins from the first semiconductor region, and forming a second set of fins from the second and third semiconductor regions.

Abstract: Transistors and methods for fabricating the same include annealing channel portions of one or more semiconductor fins that are uncovered by a protective layer in a gaseous environment to reduce fin width, to produce a fin profile that is widest at the bottom and tapers toward the top, and to round corners of the one or more semiconductor fins.

Abstract: A FinFet device structure provided with a thin layer of polycrystalline silicon having stress containing material, including a high Ge percentage silicon germanium film and/or a high stress W film on top of a polycrystalline silicon film. Space between the fins enables the stressor films to be positioned closer to the transistor channel. The improved proximity of the stress containing material to the transistor channel and the enhanced stress couple the efficiency defines a ratio between the stress level in the stressor film and stress transfer to the channel for mobility enhancement. The stress level is further enhanced by patterning by removal of the n-type workfunction metal from the p-FinFET. Following the stripping off the soft or hard mask, the p-type workfunction metal ends positioned in the n- and p-FinFET regions. The freed space specifically for p-FinFet between the fins achieves an even higher stressor coupling to further boost the carrier mobility.

Abstract: Semiconductor devices and sidewall image transfer methods with a spin on hardmask. Methods for forming fins include forming a trench through a stack of layers that includes a top and bottom insulator layer, and a layer to be patterned on a substrate; isotropically etching the top and bottom insulator layers; forming a hardmask material in the trench to the level of the bottom insulator layer; isotropically etching the top insulator layer; and etching the bottom insulator layer and the layer to be patterned down to the substrate to form fins from the layer to be patterned.

Abstract: A technique is provided for programming a transistor having a source, a drain, a gate, and a channel region between the source and the drain. The gate is above dielectric above the channel region. A gate voltage is about equal to or greater than a breakdown voltage of the gate dielectric in order to break down the gate dielectric into a breakdown state. Current flows between the source and the drain as a result of breaking down the gate dielectric. In response to the transistor being programmed, the current flowing between the source and the drain is not based on the gate voltage at the gate.

Abstract: In one embodiment, a semiconductor device is provided that includes a gate structure present on a channel portion of a fin structure. The gate structure includes a dielectric spacer contacting a sidewall of a gate dielectric and a gate conductor. Epitaxial source and drain regions are present on opposing sidewalls of the fin structure, wherein surfaces of the epitaxial source region and the epitaxial drain region that is in contact with the sidewalls of the fin structure are aligned with an outside surface of the dielectric spacer. In some embodiments, the dielectric spacer, the gate dielectric, and the gate conductor of the semiconductor device are formed using a single photoresist mask replacement gate sequence.

Abstract: A technique is provided for programming a transistor having a source, a drain, a gate, and a channel region between the source and the drain. The gate is above dielectric above the channel region. A gate voltage is about equal to or greater than a breakdown voltage of the gate dielectric in order to break down the gate dielectric into a breakdown state. Current flows between the source and the drain as a result of breaking down the gate dielectric. In response to the transistor being programmed, the current flowing between the source and the drain is not based on the gate voltage at the gate.

Abstract: Various embodiments form strained and relaxed silicon and silicon germanium fins on a semiconductor wafer. In one embodiment a semiconductor wafer is formed. The semiconductor wafer comprises a substrate, a dielectric layer, and a strained silicon germanium (SiGe) layer. At least one region of the strained SiGe layer is transformed into a relaxed SiGe region. At least one strained SiGe fin is formed from a first strained SiGe region of the strained SiGe layer. At least one relaxed SiGe fin is formed from a first portion of the relaxed SiGe region. Relaxed silicon is epitaxially grown on a second strained SiGe region of the strained SiGe layer. Strained silicon is epitaxially grown on a second portion of the relaxed SiGe region. At least one relaxed silicon fin is formed from the relaxed silicon. At least one strained silicon fin is formed from the strained silicon.

Abstract: A method for making a semiconductor device may include forming, above a substrate, a plurality of laterally spaced-apart semiconductor fins, and forming regions of a first dielectric material between the laterally spaced-apart semiconductor fins. The method may further include selectively removing at least one intermediate semiconductor fin from among the plurality of semiconductor fins to define at least one trench between corresponding regions of the first dielectric material, and forming a region of a second dielectric material different than the first dielectric in the at least one trench to provide at least one isolation pillar between adjacent semiconductor fins.