Abstract: A memory device includes a conductive wire, a first 2-D material layer, a phase change element, and a top electrode. The first 2-D material layer is over the conductive wire. The phase change element extends along a surface of the first 2-D material layer distal to the conductive layer. The top electrode is over the phase change element.

Abstract: A semiconductor device includes a substrate and a fin feature over the substrate. The fin feature includes a first portion of a first semiconductor material and a second portion of a second semiconductor material disposed over the first portion. The second semiconductor material is different from the first semiconductor material. The semiconductor device further includes a semiconductor oxide feature disposed on sidewalls of the first portion and a gate stack disposed on the fin feature. The gate stack includes an interfacial layer over a top surface and sidewalls of the second portion and a gate dielectric layer over the interfacial layer and sidewalls of the semiconductor oxide feature. A portion of the gate dielectric layer is below the interfacial layer.

Abstract: A semiconductor device includes a fin structure, a two-dimensional (2D) material channel layer, a ferroelectric layer, and a metal layer. The fin structure extends from a substrate. The 2D material channel layer wraps around at least three sides of the fin structure. The ferroelectric layer wraps around at least three sides of the 2D material channel layer. The metal layer wraps around at least three sides of the ferroelectric layer.

Abstract: Among other things, one or semiconductor arrangements, and techniques for forming such semiconductor arrangements are provided. For example, one or more silicon and silicon germanium stacks are utilized to form PMOS transistors comprising germanium nanowire channels and NMOS transistors comprising silicon nanowire channels. In an example, a first silicon and silicon germanium stack is oxidized to transform silicon to silicon oxide regions, which are removed to form germanium nanowire channels for PMOS transistors. In another example, silicon and germanium layers within a second silicon and silicon germanium stack are removed to form silicon nanowire channels for NMOS transistors. PMOS transistors having germanium nanowire channels and NMOS transistors having silicon nanowire channels are formed as part of a single fabrication process.

Abstract: A semiconductor structure includes a substrate, a first epitaxial layer, a second epitaxial layer, and a transistor. The substrate includes a first pyramid protrusion, a second pyramid protrusion, a third pyramid protrusion, and a fourth pyramid protrusion. The first and second pyramid protrusions are arranged along a first direction, the second and fourth pyramid protrusions are arranged along the first direction, and the first and third pyramid protrusions are arranged along a second direction crossing the first direction. The first epitaxial layer is over the substrate and in contact with the first, second, third, and fourth pyramid protrusions. The second epitaxial layer is over the first epitaxial layer. The transistor is over the second epitaxial layer.

Abstract: A nanowire FET device includes a vertical stack of nanowire strips configured as the semiconductor body. One or more of the top nanowire strips are receded and are shorter than the rest of the nanowire strips stacked lower. Inner spacers are uniformly formed adjacent to the receded nanowire strips and the rest of the nanowire strips. Source/drain structures are formed outside the inner spacers and a gate structure is formed inside the inner spacers, which wraps around the nanowire strips.

Abstract: In a method of manufacturing a negative capacitance structure, a dielectric layer is formed over a substrate. A first metallic layer is formed over the dielectric layer. After the first metallic layer is formed, an annealing operation is performed, followed by a cooling operation. A second metallic layer is formed. After the cooling operation, the dielectric layer becomes a ferroelectric dielectric layer including an orthorhombic crystal phase.

Abstract: A semiconductor device includes a source/drain feature disposed over a substrate. The source/drain feature includes a first nanowire, a second nanowire disposed over the first nanowire, a cladding layer disposed over the first nanowire and the second nanowire and a spacer layer extending from the first nanowire to the second nanowire. The device also includes a conductive feature disposed directly on the source/drain feature such that the conductive feature physically contacts the cladding layer and the spacer layer.

Abstract: A method for manufacturing a semiconductor structure including forming a first type semiconductor layer. The method also includes forming a semiconductor interlayer over the first type semiconductor layer. The method further includes forming a second type semiconductor layer over the semiconductor interlayer. The method further includes etching the first type semiconductor layer, the semiconductor interlayer, and the second type semiconductor layer to form a fin structure. The method further includes oxidizing the semiconductor interlayer.

Abstract: A semiconductor device includes a field effect transistor (FET). The FET includes a channel region and a source/drain region disposed adjacent to the channel region. The FET also includes a gate electrode disposed over the channel region. The FET is an n-type FET and the channel region is made of Si. The source/drain region includes an epitaxial layer including Si1?x?yM1xM2y, where M1 is one or more of Ge and Sn, and M2 is one or more of P and As, and 0.01?x?0.1.

Abstract: Devices, and methods of forming such devices, having a material that is semimetal when in bulk but is a semiconductor in the devices are described. An example structure includes a substrate, a first source/drain contact region, a channel structure, a gate dielectric, a gate electrode, and a second source/drain contact region. The substrate has an upper surface. The channel structure is connected to and over the first source/drain contact region, and the channel structure is over the upper surface of the substrate. The channel structure has a sidewall that extends above the first source/drain contact region. The channel structure comprises a bismuth-containing semiconductor material. The gate dielectric is along the sidewall of the channel structure. The gate electrode is along the gate dielectric. The second source/drain contact region is connected to and over the channel structure.

Abstract: A semiconductor test device for measuring a contact resistance includes: first fin structures, upper portions of the first fin structures protruding from an isolation insulating layer; epitaxial layers formed on the upper portions of the first fin structures, respectively; first conductive layers formed on the epitaxial layers, respectively; a first contact layer disposed on the first conductive layers at a first point; a second contact layer disposed on the first conductive layers at a second point apart from the first point; a first pad coupled to the first contact layer via a first wiring; and a second pad coupled to the second contact layer via a second wiring. The semiconductor test device is configured to measure the contact resistance between the first contact layer and the first fin structures by applying a current between the first pad and the second pad.

Abstract: In a method of manufacturing a negative capacitance structure, a dielectric layer is formed over a substrate. A first metallic layer is formed over the dielectric layer. After the first metallic layer is formed, an annealing operation is performed, followed by a cooling operation. A second metallic layer is formed. After the cooling operation, the dielectric layer becomes a ferroelectric dielectric layer including an orthorhombic crystal phase. The first metallic film includes a oriented crystalline layer.

Abstract: Provided are a memory cell and a method of forming the same. The memory cell includes a bottom electrode, an etching stop layer, a variable resistance layer, and a top electrode. The etching stop layer is disposed on the bottom electrode. The variable resistance layer is embedded in the etching stop layer and in contact with the bottom electrode. The top electrode is disposed on the variable resistance layer. A semiconductor device having the memory cell is also provided.

Abstract: A stack is formed on a substrate. The stack includes plural first epitaxial layers and plural second epitaxial layers alternatingly stacked over each other. The first epitaxial layers include sulfur, phosphorous, selenium, arsenic, or combinations thereof. A first etching process is performed on the stack to form a fin. A dielectric layer is formed over the fin. A channel region of the fin is exposed. A second etching process is performed on a first portion of each of the first epitaxial layers in the channel region of the fin using a hydrocarbon etch chemistry. The second etching process etches the first epitaxial layers at a higher etch rate than the second etching process etches the second epitaxial layers. A gate structure is formed around a first portion of each of the second epitaxial layers in the channel region of the fin.

Abstract: A method for forming a multi-gate semiconductor device includes forming a fin structure including alternating stacked first semiconductor layers and second semiconductor layers over a substrate, forming a dummy gate structure across the fin structure, forming a first spacer alongside the dummy gate structure, removing a first portion of the first spacer to expose the dummy gate structure, forming a second spacer between a second portion of first spacer and the dummy gate structure after removing the first portion of the first spacer, removing the dummy gate structure to expose a sidewall of the second spacer, removing the first semiconductor layers of the fin structure to form a plurality of nanostructures from the second semiconductor layers of the fin structure, and forming a gate conductive structure to wrap around the plurality of nanostructures. The gate conductive structure is in contact with the sidewall of the second spacer.

Abstract: A 3D-IC includes a first tier device and a second tier device. The first tier device and the second tier device are vertically stacked together. The first tier device includes a first substrate and a first interconnect structure formed over the first substrate. The second tier device includes a second substrate, a doped region formed in the second substrate, a dummy gate formed over the substrate, and a second interconnect structure formed over the second substrate. The 3D-IC also includes an inter-tier via extends vertically through the second substrate. The inter-tier via has a first end and a second end opposite the first end. The first end of the inter-tier via is coupled to the first interconnect structure. The second end of the inter-tier via is coupled to one of: the doped region, the dummy gate, or the second interconnect structure.

Abstract: In a method of manufacturing a circuit including a MOSFET disposed in a MOSFET region and a negative capacitance FET (NCFET) disposed in a NCFET region, a dielectric layer is formed over a channel layer in the MOSFET region and the NCFET region. A first metallic layer is formed over the dielectric layer in the MOSFET region and the NCFET region. After the first metallic layer is formed, an annealing operation is performed only in the NCFET region. After the annealing operation, the first metallic layer is removed from the MOSFET region and the NCFET region. The annealing operation includes irradiating the first metallic layer and the dielectric layer in the NCFET region with an energy beam.

Abstract: A semiconductor device includes a fin structure extending along a first direction, a channel layer wrapping around a top surface and opposite sidewalls of the fin structure, a gate stack extending across the channel layer along a second direction perpendicular to the first direction, and a spacer on a top surface of the channel layer and a sidewall of the gate stack when viewed in a cross section taken along the first direction. The channel layer includes a two-dimensional material. The gate stack includes a ferroelectric layer.

Abstract: Structures and formation methods of a semiconductor device structure are provided. The semiconductor device structure includes a fin structure over a semiconductor substrate. The semiconductor device structure also includes a gate stack covering a portion of the fin structure. The semiconductor device structure further includes a spacer element over a sidewall of the gate stack. The spacer element includes a first layer and a second layer over the first layer. The dielectric constant of the first layer is greater than the dielectric constant of the second layer. A gate dielectric layer of the gate stack adjoins the first layer and the second layer.