Abstract: Interconnect structures including parallel metal lines and cut regions in selected ones of the parallel metal lines are fabricated without damage, even at a very small metal pitch. A dielectric fill in the cut regions has a smaller width than the width of the metal lines. Metal line width can be increased by selective metal deposition on sidewalls of the metal lines subsequent to forming the cut regions.

Abstract: A vertical field effect transistor with a strained channel includes a channel fin structure extending vertically from a substrate. The channel fin structure being composed of a stress liner embedded within a semiconductor channel layer. The stress liner induces an uniaxial strain along a vertical direction of the channel fin structure. A high-k material is disposed along sidewalls of the semiconductor channel layer followed by a workfunction metal and a gate material. A top source/drain region is located above a top portion of the channel fin structure, and a bottom source/drain region, formed within the substrate, is located adjacent to a bottom portion of the channel fin structure.

Abstract: A mushroom memory cell may be formed by depositing a second dielectric layer on top of a first dielectric layer and a heater, depositing a hard mask on top of the second dielectric layer, performing a directional reactive-ion etching to remove an exposed portion of the second dielectric layer, performing a lateral etching to remove a portion of the second dielectric layer under the hard mask, performing directional deposition of a phase change material (PCM) over the heater, depositing a covering dielectric over the PCM, performing a second directional etching to expose a top surface of the PCM, and depositing a top electrode on the surface of the PCM.

Abstract: Embodiments of present invention provide a transistor structure. The transistor structure includes a composite channel of multiple channel layers of different materials, wherein the multiple channel layers are separated from each other by an isolation layer and a material of the isolation layer has a bandgap that is wider than bandgaps of the different materials of the multiple channel layers; a charge trapping layer surrounding the composite channel; a gate metal surrounding the charge trapping layer; and source/drain regions at a first and a second end of the composite channel. A method of forming the same is also provided.

Abstract: A semiconductor structure includes a substrate and a field effect transistor disposed on the substrate. The field effect transistor includes a vertical fin, source and drain regions separated by a gate region, a gate structure disposed over the gate region and a gate airgap spacer at least partially disposed about the gate structure.

Abstract: Embodiments of present invention provide a semiconductor structure. The semiconductor structure includes a plurality of sections from a top to a bottom thereof, wherein the plurality of sections has a same chemical composition and at least two different strains. For example, in one embodiment, the plurality of sections has a same chemical composition of epitaxially grown silicon (Si) and has alternating strains between a tensile strain and a compressive strain. A method of manufacturing the semiconductor structure is also provided.

Abstract: An approach provides a semiconductor structure with one or more rectangular or square-shaped contact vias in a semiconductor material. The semiconductor device includes one of the first element of the semiconductor device element under the square-shaped contact via or the second element of the semiconductor device element above the square-shaped contact via. The semiconductor structure includes the square-shaped via in the semiconductor material that has straight edges that are parallel to one or more of the (110) crystal planes of the semiconductor material and the square-shaped contact vias has corners pointing in a direction orthogonal to one or more of the (100) crystal planes of the semiconductor material. The square-shaped contact via provides a larger contact area that a conventional round-shaped contact via with a diameter matching the width of the square-shaped contact via.

Abstract: A method is presented for forming a nanosheet device. The method includes forming nanosheets stacks over a substrate, the nanosheet stacks separated by shallow trench isolation (STI) regions, forming a first hardmask material over the nanosheet stacks, depositing a sacrificial gate, recessing the sacrificial gate such that recesses are defined adjacent the first hardmask material, wherein a top surface of the sacrificial gate is below a top surface of the first hardmask material, forming a second hardmask material in the recesses, defining a uniform gate length in both the first and second hardmask materials, and selectively trimming the first hardmask material such that a gate length over the nanosheet stacks is less than a gate length over the STI regions.

Abstract: Provided is a stacked field-effect transistor (FET). The stacked FET comprises a top device, a bottom device, and a transition region between the top device and the bottom device. The transition region includes a plurality of inner spacers and a first inter-layer dielectric (ILD). The ILD is formed between each of the plurality of inner spacers. The top and bottom devices have a first channel sheet thickness in a gate region and a second channel sheet thickness between inner spacers. The second channel sheet thickness is larger than both the first channel sheet thickness and the first distance.

Abstract: 3D nanochannel interleaved devices for molecular manipulation are provided. In one aspect, a method of forming a device includes: forming a pattern on a substrate of alternating mandrels and spacers alongside the mandrels; selectively removing the mandrels from a front portion of the pattern forming gaps between the spacers; selectively removing the spacers from a back portion of the pattern forming gaps between the mandrels; filling i) the gaps between the spacers with a conductor to form first electrodes and ii) the gaps between the mandrels with the conductor to form second electrodes; and etching the mandrels and the spacers in a central portion of the pattern to form a channel (e.g., a nanochannel) between the first electrodes and the second electrodes, wherein the first electrodes and the second electrodes are offset from one another across the channel, i.e., interleaved. A device formed by the method is also provided.

Abstract: A semiconductor structure for a phase-change memory device includes a heater element on a portion of a bottom electrode in a first dielectric material. The semiconductor structure includes a layer of phase-change material that surrounds a portion of a second dielectric material, where the layer of phase-change material forms a three-dimensional shape around the portion of the second dielectric material. A conductive liner is under a first portion of the layer of phase-change material and surrounds a portion of a bottom surface of a hardmask layer and vertical portions of the hardmask layer. A conductive material is on a portion of a top surface of the second dielectric material and abuts the vertical portions of the layer of phase-change material below the conductive liner and the hardmask layer. A top electrode is on a top surface of the conductive material.

Abstract: An approach provides a semiconductor structure with a first crystalline surface orientation and a first nanosheet stack on the semiconductor substrate with the first crystalline surface orientation. The semiconductor substrate structure includes a second nanosheet stack with a second crystalline surface orientation above the first nanosheet stack, wherein the first nanosheet stack and the second nanosheet stack are separated by a dielectric material.

Abstract: A microelectronic structure including a stacked device region, where stacked device region is comprised of a plurality of top devices and a plurality of bottom devices. Each of the plurality of top devices includes at least one top source/drain. Each of the plurality of bottom devices includes at least one bottom source/drain. A gate cut region located adjacent to the stacked region and an interconnect located in the gate cut region. The interconnect is connected to at least two different devices located in the stacked device region.

Abstract: A method of forming a vertical transport fin field effect transistor device is provided. The method includes forming vertical fins on a substrate, depositing a protective liner on the sidewalls of the vertical fins, and removing a portion of the substrate to form a support pillar beneath at least one of the vertical fins. The method further includes etching a cavity in the support pillar of the at least one of the vertical fins, and removing an additional portion of the substrate to form a plinth beneath the support pillar of the vertical fin. The method further includes growing a bottom source/drain layer on the substrate adjacent to the plinth, and forming a diffusion plug in the cavity, wherein the diffusion plug is configured to block diffusion of dopants from the bottom source/drain layer above a necked region in the support pillar.

Abstract: A fin stack including compressively strained and tensile-strained semiconductor fin regions allows CMOS fabrication to form vertically stacked p-type FinFETs and n-type FinFETs. Aspect ratio trapping within a semiconductor base region within the fin stack provides a relaxed semiconductor base region on which uniaxially strained regions are grown. A dielectric layer may be formed to electrically isolate the compressively strained semiconductor fin region from the tensile-strained semiconductor fin region.

Abstract: A semiconductor device includes a base structure of a memory device including a first electrode, first dielectric material having a non-uniform etch rate disposed on the base structure, a via within the first dielectric material, and a ring heater within the via on the first electrode. The ring heater has a geometry based on a shape of the via that produces a resistance gradient.

Abstract: A method of forming a two dimensional (2D) vertical fin is provided. The method includes heat treating a periodic array of irregular openings in a substrate, wherein there are walls of substrate material between adjacent openings, to reduce the surface area of the openings, and etching the openings with a crystal-plane selective etch to form squared openings in the substrate.

Abstract: Embodiments of the invention include a method for fabricating a semiconductor device and the resulting structure. A first field-effect transistor (FET) having a first source/drain region is formed. A second FET having a second source/drain region is formed, where the second FET is stacked above the first FET. A trench extending from above the second source/drain region to beneath the first source/drain region is formed, where the trench passes through portions of (i) the first source/drain region and (ii) the second source/drain region. A bottom contact is formed in the trench. A dielectric layer is formed in the trench, the dielectric layer on a top surface of the bottom contact. A top contact is formed in the trench, the top contact on a top surface of the dielectric layer.

Abstract: A method of fabricating semiconductor fins, including, patterning a film stack to produce one or more sacrificial mandrels having sidewalls, exposing the sidewall on one side of the one or more sacrificial mandrels to an ion beam to make the exposed sidewall more susceptible to oxidation, oxidizing the opposite sidewalls of the one or more sacrificial mandrels to form a plurality of oxide pillars, removing the one or more sacrificial mandrels, forming spacers on opposite sides of each of the plurality of oxide pillars to produce a spacer pattern, removing the plurality of oxide pillars, and transferring the spacer pattern to the substrate to produce a plurality of fins.

Abstract: Embodiments disclosed herein include an RRAM cell. The RRAM cell may include a first nanowire electrically connected to a first wordline electrode. The nanowire may include a first sharpened point distal from the first wordline electrode. The RRAM cell may also include a metal contact electrically connected to a bitline electrode and a high-? dielectric layer directly between the nanowire and the metal contact.