Abstract: A first and a second source drain region, an upper source drain contact connected to the first source drain region, a bottom source drain contact connected to the second source drain region, a dielectric spacer surrounds opposite vertical side surfaces of the bottom source drain contact and overlaps a vertical side surface and a lower horizontal surface of a bottom isolation region. A width of the bottom source drain contact wider than a width of the second source drain. Forming an undoped silicon buffer epitaxy in an opening between and below a first and a second nanosheet stack, forming a contact to a first source drain adjacent to that, removing the undoped silicon buffer epitaxy below a second source drain between the first and the second nanosheet stack, forming a bottom contact to that, a width of the bottom contact is wider than a width of the second source drain.

Abstract: An approach that provides a method for forming a semiconductor structure with a gate jumper. The semiconductor structure includes a source/drain contact for a semiconductor device and a dielectric cap on a top portion of the source/drain contact. The semiconductor structure includes two gates adjacent to the source/drain contact. The semiconductor structure includes a gate jumper that connects the two gates adjacent to the source/drain contact. The gate jumper surrounds the dielectric cap on the top portion of the source/drain contact. In other embodiments, the gate jumper is over two or more dielectric caps on two or more source/drain contacts and the gate jumper connects three or more adjacent gates that surround a bottom portion of each of the two or more source/drain contacts.

Abstract: A semiconductor device is provided. The semiconductor device includes a semiconductor device comprising: a bottom field effect transistor (FET); a top FET stacked over the bottom FET, where the top FET has a smaller active area than the bottom FET; a bottom gate formed in contact with the bottom FET; a top gate formed in contact with the top FET; and a bottom contact formed adjacent to the top gate, wherein an inner spacer is formed between the bottom contact and the top gate.

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 semiconductor device and formation thereof. The semiconductor device includes a plurality of fins grouped in a fin array. A first profile of an upper portion of each of the plurality of fins in the fin array located above a top surface of a shallow trench isolation layer is substantially similar. A second profile of a bottom portion of one or more inner fins in the fin array located below the shallow trench isolation layer is different than a third profile of the bottom portion of edge fins in the fin array located below the shallow trench isolation layer. A width of the bottom portion of the edge fins in the fin array located below the shallow trench isolation layer is greater than a width of the bottom portion of the one or more inner fins in the fin array located below the shallow trench isolation layer.

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: A method of manufacturing an RRAM cell includes forming a first wire, forming an insulator on the first wire, the insulator having a pore and an insulator surface, and forming a first electrode layer on the first wire and the insulator, the first electrode having an electrode surface. The method further includes recessing the first electrode layer such that the electrode surface is recessed toward the first wire from the insulator surface, forming a switching layer on the insulator and the first electrode, and forming a second electrode on the switching layer.

Abstract: Embodiments of the invention include a method for fabricating a semiconductor device and the resulting structure. A nanosheet stack of alternating nanosheets of a sacrificial semiconductor material nanosheet and a semiconductor channel material nanosheet and adjacent source/drain regions are provided, where a dummy gate having a gate cut straddles over the nanosheet stack. A semiconductor layer is wafer bonded. A fin is patterned in the semiconductor layer. A source/drain region is formed. A spacer is formed on the bottom source/drain region. A dummy gate is formed on sidewalls of a portion of the fin. A source/drain region is formed. A trench is formed that passes through one dummy gate to the other dummy gate. The dummy gates are removed. Each sacrificial semiconductor material nanosheet is removed. Functional gate structures are formed in regions occupied by the dummy gates and each sacrificial semiconductor material nanosheet.

Abstract: A semiconductor device includes a first semiconductor layer and a second semiconductor layer. The first semiconductor layer of the semiconductor device includes a standard-gate field-effect transistor. The second semiconductor layer of the semiconductor device includes an extended-gate field-effect transistor. The first semiconductor layer and the second semiconductor layer are formed on top of one another.

Abstract: Embodiments are disclosed for a system. The system includes a semiconductor structure. The semiconductor structure includes a wafer, multiple transistors, and a magnetoresistive random access memory (MRAM) cell disposed on the backside of the wafer. The transistors are disposed on a front end of line (FEOL) of the wafer. The MRAM cell is connected to a source-drain of the transistors by a contact disposed on the backside of the wafer. The transistors are in direct electrical contact with the MRAM cell by at least one contact.

Abstract: Semiconductor devices and methods of forming the same include forming a multilayer dielectric structure, including a first dielectric layer and a second dielectric layer, between dielectric lines. Exposed portions of the first dielectric layer are etched away, leaving remnants between the second dielectric layer and the dielectric lines, to decrease a width of the multilayer dielectric structure. Conductive lines are formed between the dielectric lines, on respective sides of the multilayer dielectric structure.

Abstract: Disclosed are DRAM devices and methods of forming DRAM devices. One method may include forming a plurality of trenches and angled structures, each angled structure including a first sidewall opposite a second sidewall, wherein the second sidewall extends over an adjacent trench. The method may include forming a spacer along a bottom surface of the trench, along the second sidewall, and along the first sidewall, wherein the spacer has an opening at a bottom portion of the first sidewall. The method may include forming a drain in each of the angled structures by performing an ion implant, which impacts the first sidewall through the opening at the bottom portion of the first sidewall. The method may include removing the spacer from the first sidewall, forming a bitline over the spacer along the bottom surface of each of the trenches, and forming a series of wordlines along the angled structures.

Abstract: Disclosed are approaches for forming a semiconductor device. In some embodiments, a method may include providing a patterned hardmask over a substrate, and providing, from an ion source, a plasma treatment to a first section of the patterned hardmask, wherein a second section of the patterned hardmask does not receive the plasma treatment. The method may further include etching the substrate to form a plurality of fins in the substrate, wherein the first section of the patterned hardmask is etched faster than the second section of the patterned hardmask.

Abstract: A method, apparatus, and manufacturing system are disclosed herein for a vertical field effect transistor patterned in a self-aligned process. A plurality of fins is formed. A gate structure is formed on at least a first side and a second side of a lower portion of each fin. A spacer is formed on at least a first side and a second side of an upper portion of each fin. At least one layer is formed above the substrate and between the fins. An opening is formed in the at least one layer between the fins by an etching process. The spacer protects the gate structure during the etching process.

Abstract: A method, apparatus, and manufacturing system are disclosed herein for a vertical field effect transistor patterned in a self-aligned process. A plurality of fins is formed. A gate structure is formed on at least a first side and a second side of a lower portion of each fin. A spacer is formed on at least a first side and a second side of an upper portion of each fin. At least one layer is formed above the substrate and between the fins. An opening is formed in the at least one layer between the fins by an etching process. The spacer protects the gate structure during the etching process.

Abstract: Disclosed are approaches for forming a semiconductor device. In some embodiments, a method may include providing a patterned hardmask over a substrate, and providing, from an ion source, a plasma treatment to a first section of the patterned hardmask, wherein a second section of the patterned hardmask does not receive the plasma treatment. The method may further include etching the substrate to form a plurality of fins in the substrate, wherein the first section of the patterned hardmask is etched faster than the second section of the patterned hardmask.

Abstract: Methods herein may include forming a gate dielectric within a set of trenches in a stack of layers. A first work function (WF) metal may be formed atop the gate dielectric, and a capping layer may be formed over the first WF metal using an angled ion implant deposition, the capping layer extending across the trenches.

Abstract: Disclosed are approaches for forming finFET devices having asymmetric fins achieved via fin trimming. In some embodiments, a method may include providing a substrate within a process chamber, the substrate including a plurality of fins, and forming a capping layer over the plurality of fins, wherein the capping layer extends along a first sidewall and a second sidewall of each of the plurality of fins. The method may further include removing a portion of the capping layer to expose a target area of the first sidewall of each of the plurality of fins, and trimming the target area of the first sidewall of each of the plurality of fins to reduce a lateral width of an upper section of each of the plurality of fins.

Abstract: Disclosed are approaches for forming finFET devices having asymmetric fins achieved via fin trimming. In some embodiments, a method may include providing a substrate within a process chamber, the substrate including a plurality of fins, and forming a capping layer over the plurality of fins, wherein the capping layer extends along a first sidewall and a second sidewall of each of the plurality of fins. The method may further include removing a portion of the capping layer to expose a target area of the first sidewall of each of the plurality of fins, and trimming the target area of the first sidewall of each of the plurality of fins to reduce a lateral width of an upper section of each of the plurality of fins.

Abstract: Disclosed are DRAM devices and methods of forming DRAM devices. One method may include forming a plurality of trenches and angled structures, each angled structure including a first sidewall opposite a second sidewall, wherein the second sidewall extends over an adjacent trench. The method may include forming a spacer along a bottom surface of the trench, along the second sidewall, and along the first sidewall, wherein the spacer has an opening at a bottom portion of the first sidewall. The method may include forming a drain in each of the angled structures by performing an ion implant, which impacts the first sidewall through the opening at the bottom portion of the first sidewall. The method may include removing the spacer from the first sidewall, forming a bitline over the spacer along the bottom surface of each of the trenches, and forming a series of wordlines along the angled structures.