Abstract: Various methods for fabricating non-planar integrated circuit devices, such as FinFET devices, are disclosed herein. An exemplary method includes forming a rib structure extending from a substrate; forming a two-dimensional material layer (including, for example, transition metal dichalcogenide or graphene) on the rib structure and the substrate; patterning the two-dimensional material layer, such that the two-dimensional material layer is disposed on at least one surface of the rib structure; and forming a gate on the two-dimensional material layer. In some implementations, a channel region, a source region, and a drain region are defined in the two-dimensional material layer. The channel region is disposed between the source region and the drain region, where the gate is disposed over the channel region. In some implementations, the patterning includes removing the two-dimensional material layer disposed on a top surface of the substrate and/or disposed on a top surface of the rib structure.

Abstract: A crystalline channel layer of a semiconductor material is formed in a backend process over a crystalline dielectric seed layer. A crystalline magnesium oxide MgO is formed over an amorphous inter-layer dielectric layer. The crystalline MgO provides physical link to the formation of a crystalline semiconductor layer thereover.

Abstract: A field effect transistor includes a semiconductor substrate, a first pad layer, carbon nanotubes and a gate structure. The first pad layer is disposed over the semiconductor substrate and comprises a 2D material. The carbon nanotubes are disposed over the first insulating pad layer. The gate structure is disposed over the semiconductor substrate and is vertically stacked with the carbon nanotubes. The carbon nanotubes extend from one side to an opposite side of the gate structure.

Abstract: Various methods for fabricating non-planar integrated circuit devices, such as FinFET devices, are disclosed herein. An exemplary method includes forming a rib structure extending from a substrate; forming a two-dimensional material layer (including, for example, transition metal dichalcogenide or graphene) on the rib structure and the substrate; patterning the two-dimensional material layer, such that the two-dimensional material layer is disposed on at least one surface of the rib structure; and forming a gate on the two-dimensional material layer. In some implementations, a channel region, a source region, and a drain region are defined in the two-dimensional material layer. The channel region is disposed between the source region and the drain region, where the gate is disposed over the channel region. In some implementations, the patterning includes removing the two-dimensional material layer disposed on a top surface of the substrate and/or disposed on a top surface of the rib structure.

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: Provided herein are wafers that can be used to align carbon nanotubes, as well as methods of making and using the same. Such wafers include alignment areas that have four sides and a surface charge, where the alignment areas are surrounded by areas that have a surface charge of a different polarity. Methods of the disclosure may include depositing and selectively etching a number of hardmasks on a substrate. The described methods may also include depositing a carbon nanotube on such a wafer.

Abstract: Provided herein are wafers that can be used to align carbon nanotubes, as well as methods of making and using the same. Such wafers include alignment areas that have four sides and a surface charge, where the alignment areas are surrounded by areas that have a surface charge of a different polarity. Methods of the disclosure may include depositing and selectively etching a number of hardmasks on a substrate. The described methods may also include depositing a carbon nanotube on such a wafer.

Abstract: In a method of forming a gate-all-around field effect transistor (GAA FET), a fin structure is formed. The fin structure includes a plurality of stacked structures each comprising a dielectric layer, a CNT over the dielectric layer, a support layer over the CNT. A sacrificial gate structure is formed over the fin structure, an isolation insulating layer is formed, a source/drain opening is formed by patterning the isolation insulating layer, the support layer is removed from each of the plurality of stacked structures in the source/drain opening, and a source/drain contact layer is formed in the source/drain opening. The source/drain contact is formed such that the source/drain contact is in direct contact with only a part of the CNT and a part of the dielectric layer is disposed between the source/drain contact and the CNT.

Abstract: Among other things, one or more techniques for forming a vertical tunnel field effect transistor (FET), and a resulting vertical tunnel FET are provided herein. In an embodiment, the vertical tunnel FET is formed by forming a core over a first type substrate region, forming a second type channel shell around a circumference greater than a core circumference, forming a gate dielectric around a circumference greater than the core circumference, forming a gate electrode around a circumference greater than the core circumference, and forming a second type region over a portion of the second type channel shell, where the second type has a doping opposite a doping of the first type. In this manner, line tunneling is enabled, thus providing enhanced tunneling efficiency for a vertical tunnel FET.

Abstract: A semiconductor arrangement includes a semiconductor layer having a source/drain region and a first epitaxial layer over the semiconductor layer. The semiconductor arrangement includes a second epitaxial layer over the first epitaxial layer, wherein the first epitaxial layer and the second epitaxial layer define a contact structure for the source/drain region.

Abstract: A method includes forming a first epitaxial layer having a first dopant over a substrate; etching the first epitaxial layer to form a fin with a polar sidewall; and forming in sequence a semiconductor interlayer and a second epitaxial layer to surround the fin, in which the second epitaxial layer has a second dopant with a different conductivity type than the first dopant.

Abstract: In a method of forming a gate-all-around field effect transistor (GAA FET), a bottom support layer is formed over a substrate and a first group of carbon nanotubes (CNTs) are disposed over the bottom support layer. A first support layer is formed over the first group of CNTs and the bottom support layer such that the first group of CNTs are embedded in the first support layer. A second group of carbon nanotubes (CNTs) are disposed over the first support layer. A second support layer is formed over the second group of CNTs and the first support layer such that the second group of CNTs are embedded in the second support layer. A fin structure is formed by patterning at least the first support layer and the second support layer.

Abstract: In a method of forming a Group III-V semiconductor layer on a Si substrate, a first source gas containing a Group V element is supplied to a surface of the Si substrate while heating the substrate at a first temperature, thereby terminating the Si surface with the Group V element. Then, a second source gas containing a Group III element is supplied to the surface while heating the substrate at a second temperature, thereby forming a nucleation layer directly on the surface of the Si substrate. After the nucleation layer is formed, the supply of the second source gas is stopped and the substrate is annealed at a third temperature while the first source gas being supplied, thereby forming a seed layer. After the annealing, the second source gas is supplied while heating the substrate at a fourth temperature, thereby forming a body III-V layer semiconductor on the seed layer.

Abstract: The current disclosure describes a tunnel FET device including a P-I-N heterojunction structure. A high-K dielectric layer and a metal gate wrap around the intrinsic channel layer with an interlayer positioned between high-K dielectric layer and the intrinsic channel layer of the P-I-N heterojunction. The interlayer prevents charge carriers from reaching the interface with high-K dielectric layer under the trap-assisted tunneling effect and reduces OFF state leakage.

Abstract: The current disclosure describes a tunnel FET device including a P-I-N heterojunction structure. A high-K dielectric layer and a metal gate wrap around the intrinsic channel layer with an interlayer positioned between high-K dielectric layer and the intrinsic channel layer of the P-I-N heterojunction. The interlayer prevents charge carriers from reaching the interface with high-K dielectric layer under the trap-assisted tunneling effect and reduces OFF state leakage.

Abstract: In a method of forming a gate-all-around field effect transistor (GAA FET), a bottom support layer is formed over a substrate and a first group of carbon nanotubes (CNTs) are disposed over the bottom support layer. A first support layer is formed over the first group of CNTs and the bottom support layer such that the first group of CNTs are embedded in the first support layer. A second group of carbon nanotubes (CNTs) are disposed over the first support layer. A second support layer is formed over the second group of CNTs and the first support layer such that the second group of CNTs are embedded in the second support layer. A fin structure is formed by patterning at least the first support layer and the second support layer.

Abstract: The current disclosure describes a vertical tunnel FET device including a vertical P-I-N heterojunction structure of a P-doped nanowire gallium nitride source/drain, an intrinsic InN layer, and an N-doped nanowire gallium nitride source/drain. A high-K dielectric layer and a metal gate wrap around the intrinsic InN layer.

Abstract: A gate-all-around field effect transistor (GAA FET) includes an InAs nano-wire as a channel layer, a gate dielectric layer wrapping the InAs nano-wire, and a gate electrode metal layer formed on the gate dielectric layer. The InAs nano-wire has first to fourth major surfaces three convex-rounded corner surfaces and one concave-rounded corner surface.

Abstract: The current disclosure describes a tunnel FET device including a P-I-N heterojunction structure. A high-K dielectric layer and a metal gate wrap around the intrinsic channel layer with an interlayer positioned between high-K dielectric layer and the intrinsic channel layer of the P-I-N heterojunction. The interlayer prevents charge carriers from reaching the interface with high-K dielectric layer under the trap-assisted tunneling effect and reduces OFF state leakage.

Abstract: A method includes forming a first epitaxial layer having a first dopant over a substrate; etching the first epitaxial layer to form a fin with a polar sidewall; and forming in sequence a semiconductor interlayer and a second epitaxial layer to surround the fin, in which the second epitaxial layer has a second dopant with a different conductivity type than the first dopant.