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: A method of fabricating a semiconductor device includes forming a fin structure on a substrate, forming a channel layer on a sidewall and a top surface of the fin structure, and forming a gate stack over the channel layer. The channel layer includes a two-dimensional (2D) material. The gate stack includes a ferroelectric layer.

Abstract: In a method of manufacturing a semiconductor device, a fin structure is formed over a substrate. The fin structure is sculpted to have a plurality of non-etched portions and a plurality of etched portions having a narrower width than the plurality of non-etched portions. The sculpted fin structure is oxidized so that a plurality of nanowires are formed in the plurality of non-etched portions, respectively, and the plurality of etched portions are oxidized to form oxides. The plurality of nanowires are released by removing the oxides.

Abstract: In a method of manufacturing a semiconductor device, a fin structure is formed over a substrate. The fin structure is sculpted to have a plurality of non-etched portions and a plurality of etched portions having a narrower width than the plurality of non-etched portions. The sculpted fin structure is oxidized so that a plurality of nanowires are formed in the plurality of non-etched portions, respectively, and the plurality of etched portions are oxidized to form oxides. The plurality of nanowires are released by removing the oxides.

Abstract: A semiconductor device includes a first potential supply line for supplying a first potential, a second potential supply line for supplying a second potential lower than the first potential, a functional circuit, and at least one of a first switch disposed between the first potential supply line and the functional circuit and a second switch disposed between the second potential supply line and the functional circuit. The first switch and the second switch are negative capacitance FET.

Abstract: In a method of manufacturing a negative capacitance structure, a ferroelectric dielectric layer is formed over a first conductive layer disposed over a substrate, and a second conductive layer is formed over the ferroelectric dielectric layer. The ferroelectric dielectric layer includes an amorphous layer and crystals.

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: Disclosed herein is a method for forming a test key system for characterizing wafer processing states, the method comprising forming a plurality of shallow trench isolation structures (STIs) on a substrate of a wafer and in a scribe line of the wafer and forming a test key on the substrate of a wafer and in the scribe line of the wafer. Forming the test key comprises forming at least one test key group having a plurality of test key series, each of the plurality of test key series having a plurality of test pads, each one of the plurality of test key series having a first physical characteristic different from the first physical characteristic of other test key series the at least one first test key group.

Abstract: A transistor that is formed with a transition metal dichalcogenide material is provided. The transition metal dichalcogenide material is formed using a direct deposition process and patterned into one or more fins. A gate dielectric and a gate electrode are formed over the one or more fins. Alternatively, the transition metal dichalcogenide material may be formed using a deposition of a non-transition metal dichalcogenide material followed by a treatment to form a transition metal dichalcogenide material. Additionally, fins that utilized the transition metal dichalcogenide material may be formed with sidewalls that are either perpendicular to a substrate or else are sloped relative to the substrate.

Abstract: The disclosed technique forms epitaxy layers locally within a trench having angled recesses stacked in the sidewall of the trench. The sizes of the recesses are controlled to control the thickness of the epitaxy layers to be formed within the trench. The recesses are covered by cap layers and exposed one by one sequentially beginning from the lowest recess. The epitaxy layers are formed one by one within the trench with the facet edge portion thereof aligned into the respective recess, which is the recess sequentially exposed for the epitaxy layer.

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 including a field effect transistor (FET) device includes a substrate and a channel structure formed of a two-dimensional (2D) material. An interfacial layer is formed on the channel structure. A gate stack including a gate electrode layer and a gate dielectric layer is formed over the interfacial layer. Source and drain contacts are formed over openings in the interfacial layer. The source and drain contacts have a side contact with the interfacial layer and a side contact and a surface contact with the channel structure.

Abstract: Present disclosure provides gate-all-around structure including a semiconductor fin having a top surface, a first nanowire over the top surface, a first space between the top surface and the first nanowire, an Nth nanowire and an (N+1)th nanowire over the first nanowire, and a second space between the Nth nanowire and the (N+1)th nanowire. The first space is greater than the second space. Present disclosure also provides a method for manufacturing the gate-all-around structure described herein.

Abstract: A semiconductor device includes a fin structure, a channel layer and a gate stack. The channel layer is disposed on sidewalls of the fin structure, wherein the channel layer contains a two-dimensional (2D) material. The gate stack is disposed over the channel layer, wherein the gate stack includes a ferroelectric layer.

Abstract: Exemplary FET devices having 2D material layer active regions and methods of fabricating thereof are described. For example, a black phosphorus active region has a first thickness in the channel region and a second, greater, thickness in the source/drain (S/D) region. The BP in the S/D region has a sidewall that interfaces a contact disposed over the FET. A gate electrode is disposed over the channel region. In some embodiments, the sidewall has passivated edge. In some embodiments, the sidewall is nonlinear. In some embodiments, the stress layer is disposed over the 2D material layer.

Abstract: A negative capacitance device includes a semiconductor layer. An interfacial layer is disposed over the semiconductor layer. An amorphous dielectric layer is disposed over the interfacial layer. A ferroelectric layer is disposed over the amorphous dielectric layer. A metal gate electrode is disposed over the ferroelectric layer. At least one of the following is true: the interfacial layer is doped; the amorphous dielectric layer has a nitridized outer surface; a diffusion-barrier layer is disposed between the amorphous dielectric layer and the ferroelectric layer; or a seed layer is disposed between the amorphous dielectric layer and the ferroelectric layer.

Abstract: Disclosed herein is a method for forming a test key system for characterizing wafer processing states, the method comprising forming a plurality of shallow trench isolation structures (STIs) on a substrate of a wafer and in a scribe line of the wafer and forming a test key on the substrate of a wafer and in the scribe line of the wafer. Forming the test key comprises forming at least one test key group having a plurality of test key series, each of the plurality of test key series having a plurality of test pads, each one of the plurality of test key series having a first physical characteristic different from the first physical characteristic of other test key series the at least one first test key group.

Abstract: A method for forming a multi-gate semiconductor device includes providing a substrate including at least a fin structure and a dummy gate structure over the fin structure and the substrate, disposing a conductive spacer over sidewalls of the dummy gate structure, portions of the fin structure are exposed from the dummy gate structure and the conductive spacer, forming a source/drain region in the portions of the fin structures exposed from the dummy gate structure and the conductive spacer, disposing a dielectric structure over the substrate, removing the dummy gate structure to form a gate trench in the dielectric structure, the conductive spacer is exposed from sidewalls of the gate trench, disposing at least a gate dielectric layer over a bottom of the gate trench, and disposing a gate conductive structure in the gate trench, sidewalls of the gate conductive structure are in contact with the conductive spacer.

Abstract: An integrated semiconductor device includes a first semiconductor device, an ILD layer and a second semiconductor device. The semiconductor device has a first transistor structure. The ILD layer is over the semiconductor device and has a thickness in a range substantially from 10 nm to 100 nm. The second semiconductor device is over the ILD layer and has a 2D material layer as a channel layer of a second transistor structure thereof.