Abstract: Techniques for dielectric isolation in bulk nanosheet devices are provided. In one aspect, a method of forming a nanosheet device structure with dielectric isolation includes the steps of: optionally implanting at least one dopant into a top portion of a bulk semiconductor wafer, wherein the at least one dopant is configured to increase an oxidation rate of the top portion of the bulk semiconductor wafer; forming a plurality of nanosheets as a stack on the bulk semiconductor wafer; patterning the nanosheets to form one or more nanowire stacks and one or more trenches between the nanowire stacks; forming spacers covering sidewalls of the nanowire stacks; and oxidizing the top portion of the bulk semiconductor wafer through the trenches, wherein the oxidizing step forms a dielectric isolation region in the top portion of the bulk semiconductor wafer. A nanowire FET and method for formation thereof are also provided.

Abstract: Embodiments of the present disclosure provide a semiconductor structure including a first sidewall spacer positioned between a first gate terminal and a first source/drain terminal of a first active device. The first sidewall spacer includes a first L-shaped spacer and a first outer spacer. The L-shaped spacer having a base portion and a vertical portion vertically extended, parallel to the first outer spacer, to a top portion of a first inter dielectric layer (IDL). A RDB dielectric, having a reduced width less than a width of the first gate terminal. The RDB dielectric vertically extends from the top portion of the IDL into the substrate. The RDB dielectric is separated from the first source/drain terminal by first RDB spacer, the first RDB spacer includes a first upper spacer. The first RDB spacer has a reduced width less that the first sidewall spacer width.

Abstract: A method, phase change memory array, and system for controlling heater height variation in phase change memories using a multi-step selective stop method. The method may include depositing a first dielectric layer. The method may also include depositing a second dielectric layer proximately connected to the first dielectric layer, where the second dielectric layer is different than the first dielectric layer. The method may also include depositing a heating material. The method may also include performing a first selective stop to remove excess heating material above the second dielectric layer. The method may also include performing a second selective stop to remove the second dielectric layer.

Abstract: A phase change bridge memory cell includes: a first interlevel dielectric layer; a first electrode and a second electrode disposed in the first interlevel dielectric layer and separated by a portion of the first interlevel dielectric layer; an interlevel dielectric pillar on the portion of the first interlevel dielectric layer; a first phase change material on the interlevel dielectric pillar; and a second phase change material including two areas on opposite sides of the interlevel dielectric pillar and electrically connected by the first phase change material, wherein the second phase change material is connected to the first electrode and the second electrode.

Abstract: Embodiments herein describe semiconductor devices with single diffusion breaks that are narrower than the gates of transistors in those devices. That is, rather than forming the diffusion breaks using a dummy gate (which would result in the diffusion breaks having the same width as the gates of the transistors) the embodiments herein use different means to establish the width of the diffusion break. As a result, the diffusion break can be narrower than traditional diffusion breaks formed using dummy gates, thereby saving area in the semiconductor device.

Abstract: Fabricating a nanosheet transistor includes receiving a substrate structure having a set of nanosheet layers stacked upon a substrate, the set of nanosheet layers including at least one silicon (Si) layer, at least one silicon-germanium (SiGe) layer, a fin formed in the nanosheet layers, a gate region formed within the fin, and a trench region adjacent to the fin. A top sacrificial spacer is formed upon the fin and the trench region and etched to form a trench in the trench region. An indentation is formed within the SiGe layer in the trench region, and a sacrificial inner spacer is formed within the indentation. A source/drain (S/D) region is formed within the trench. The sacrificial top spacer and sacrificial inner spacer are etched to form an inner spacer cavity between the S/D region and the SiGe layer. An inner spacer is formed within the inner spacer cavity.

Abstract: Stacked nanosheet complementary metal-oxide-semiconductor field effect transistor devices include a lower semiconductor channel sheet on a substrate. An upper semiconductor channel sheet is on the substrate above the lower semiconductor channel sheet. The upper semiconductor channel sheet is a different semiconductor material than the lower semiconductor channel sheet. A dielectric substitute partition sheet is on the substrate between the upper semiconductor channel sheet and the lower semiconductor channel sheet.

Abstract: A method of forming a transistor device is provided. The method includes forming a plurality of gate structures including a gate spacer and a gate electrode on a substrate, wherein the plurality of gate structures are separated from each other by a source/drain contact. The method further includes reducing the height of the gate electrodes to form gate troughs, and forming a gate liner on the gate electrodes and gate spacers. The method further includes forming a gate cap on the gate liner, and reducing the height of the source/drain contacts between the gate structures to form a source/drain trough. The method further includes forming a source/drain liner on the source/drain contacts and gate spacers, wherein the source/drain liner is selectively etchable relative to the gate liner, and forming a source/drain cap on the source/drain liner.

Abstract: A semiconductor structure for a vertical phase change memory cell that includes a bottom electrode on a portion of a semiconductor substrate and a pair of vertical phase change bridge elements that are each on a portion of the bottom electrode. The semiconductor structure for the vertical phase change memory cell includes a dielectric material separating the pair of vertical phase change bridge elements and a top electrode over the pair of vertical phase change bridge elements.

Abstract: A phase change memory includes a phase change structure. There is a heater coupled to a first surface of the phase change structure. A first electrode is coupled to a second surface of the phase change structure. A second electrode coupled to a second surface of the heater. A third electrode is connected to a first lateral end of the phase change structure and a fourth electrode connected to a second lateral end of the phase change structure.

Abstract: A gate-all-around field effect transistor device is provided. The gate-all-around field effect transistor device includes one or more channel layers on a substrate. The gate-all-around field effect transistor device further includes an inner spacer wrapped around four sides of an end portion of each of the one or more channel layers. The gate-all-around field effect transistor device further includes a portion of an inner spacer liner between a portion of an upper most channel layer and a portion of an outer spacer.

Abstract: A phase change memory (PCM) device is provided. The PCM device includes a bottom electrode formed on a substrate, a heater electrode formed on the bottom electrode, the heater electrode having a tapered portion that becomes narrower in a direction away from the substrate. The PCM device also includes an interlayer dielectric (ILD) layer formed on the tapered portion of the heater electrode, the interlayer layer dielectric including an airgap that at least partially surrounds the tapered portion of the heater electrode. The PCM device also includes a phase change layer formed on the heater electrode, and a top electrode formed on the phase change layer.

Abstract: A phase change memory element including at least one phase change material layer, and a heater conductor, wherein at least a portion of the heater conductor is circumferentially surrounded by the at least one phase change material layer. The phase change memory element is symmetrical. The phase change memory element can include a top electrode circumferentially surrounding and connected to the at least one phase change material layer, and a bottom electrode in contact with the heater conductor. The phase change memory element can include at least one resistive liner in contact with the at least one phase change material layer.

Abstract: A semiconductor device having a self-aligned contact gate dielectric cap, or “SAC cap” over the gate stack and spacer. A SAC cap ear exists over the sidewall of a top portion of the spacer at a location where no S/D contact is formed. A method of forming the semiconductor device comprises: (i) forming gate stack; (ii) recessing ILD to create topography of the gate stack; (iii) forming selective gate cap deposition over the gate stack; and/or (iv) forming self-aligned contact with respect to the selective gate cap.

Abstract: Semiconductor devices and methods of forming the same include forming dummy gate spacers in a trench in a semiconductor substrate. A dummy gate is formed in the trench. An exposed dummy gate spacer is replaced with a sacrificial spacer. A cap layer is formed over the dummy gate. The cap layer is etched to expose the dummy gate. The sacrificial spacer is replaced with an isolation dielectric spacer. The dummy gate is replaced with a conductor.

Abstract: A device comprises a first interconnect structure, a second interconnect structure, a stacked complementary transistor structure, a first contact, and a second contact. The stacked complementary transistor structure is disposed between the first and second interconnect structures. The stacked complementary transistor structure comprises a first transistor of a first type, and a second transistor of a second type which is opposite the first type. The first contact connects a first source/drain element of the first transistor to the first interconnect structure. The second contact connects a first source/drain element of the second transistor to the second interconnect structure. The first and second contacts are disposed in alignment with each other.

Abstract: Nanopore structures are provided. In one aspect, a nanopore structure includes: an oxide shell surrounding a nanopore, wherein openings on both ends of the nanopore have a diameter D1, and a center of the nanopore has a diameter D2, wherein D1>D2. In another aspect, the nanopore structure includes: a first film disposed on a substrate; a second film disposed on the first film; at least one pore extending through the first film and the second film; a dielectric material disposed in the at least one pore; and a nanopore at a center of the dielectric material in the at least one pore, wherein a top opening to the nanopore has a first diameter d1, and a bottom opening to the nanopore has a second diameter d2, wherein d2>d1. Methods of forming the nanopore structures are also provided.

Abstract: Embodiments of the invention are directed to a method of forming a semiconductor device. A non-limiting example of the method includes performing fabrication operations to form a field effect transistor (FET) device on a substrate. The fabrication operations include forming a channel region over the substrate, forming a bottom conductive layer of a wrap-around source or drain (S/D) contact over the substrate, and forming a S/D region over the bottom conductive layer and adjacent to the channel region. The S/D region is communicatively coupled to the channel region and the bottom conductive layer.

Abstract: Systems, computer-implemented methods, and computer program products that can facilitate elevator analytics and/or elevator optimization components are provided. According to an embodiment, a system can comprise a memory that stores computer executable components and a processor that executes the computer executable components stored in the memory. The computer executable components can comprise a prediction component that can predict a current destination of an elevator passenger based on historical elevator usage data of the elevator passenger. The computer executable components can further comprise an assignment component that can assign the elevator passenger to an elevator based on the current destination.

Abstract: A method including forming a plurality of nanosheet layers on a substrate and forming a plurality of first sacrificial layers on the substrate, wherein the plurality of nanosheet layers and the plurality of first sacrificial layers are arranged in alternating layers, where the plurality of first sacrificial layers is comprised of a first material. Selectively removing the plurality of first sacrificial layers and forming a plurality of second sacrificial layers where the plurality of first sacrificial layers were removed, where the plurality of second sacrificial layers is comprised of a second material, where the first material and the second material are different. Recessing the plurality of second sacrificial layers at an even rate.