Thin film transistors having fin structures integrated with two-dimensional (2D) channel materials are described. In an example, an integrated circuit structure includes a plurality of insulator fins above a substrate. A two-dimensional (2D) material layer is over the plurality of insulator fins. A gate dielectric layer is on the 2D material layer. A gate electrode is on the gate dielectric layer. A first conductive contact is on the 2D material layer adjacent to a first side of the gate electrode. A second conductive contact is on the 2D material layer adjacent to a second side of the gate electrode, the second side opposite the first side.

A vertical field effect transistor according to an embodiment of the present invention does not require a spacer and, accordingly, remarkably alleviates the problem that electric charge is scattered at an interface, thereby having excellent electrical characteristics. The vertical field effect transistor includes a substrate, a source electrode positioned on the substrate, an active layer positioned on the source electrode and having vertically grown crystal grains, a drain electrode positioned on the active layer to be spaced by the active layer away from the source electrode, a gate insulating layer positioned on a lateral surface of the active layer, and a gate electrode positioned on the gate insulating layer.

A semiconductor structure includes a semiconductor substrate, a plurality of stacked units, a conductive structure, a plurality of dielectrics, a first electrode strip, a second electrode strip, and a plurality of contact structures. The stacked units are stacked up over the semiconductor substrate, and comprises a first passivation layer, a second passivation layer and a channel layer sandwiched between the first passivation layer and the second passivation layer. The conductive structure is disposed on the semiconductor substrate and wrapping around the stacked units. The dielectrics are surrounding the stacked units and separating the stacked units from the conductive structure. The first electrode strip and the second electrode strip are located on two opposing sides of the conductive structure. The contact structures are connecting the channel layer of each of the stacked units to the first electrode strip and the second electrode strip.

Thin film transistors having CMOS functionality integrated with two-dimensional (2D) channel materials are described. In an example, an integrated circuit structure includes a first device including a first two-dimensional (2D) material layer, and a first gate stack around the first 2D material layer. The first gate stack has a gate electrode around a gate dielectric layer. A second device is stacked on the first device. The second device includes a second 2D material layer, and a second gate stack around the second 2D material layer. The second gate stack has a gate electrode around a gate dielectric layer. The second 2D material layer has a composition different than a composition of the first 2D material layer.

A reinforced thin-film device (100, 200, 500) including a substrate (101) having a top surface for supporting an epilayer; a mask layer (103) patterned with a plurality of nanosize cavities (102, 102′) disposed on said substrate (101) to form a needle pad; a thin-film (105) of lattice-mismatched semiconductor disposed on said mask layer (103), wherein said thin-film (105) comprises a plurality of in parallel spaced semiconductor needles (104, 204) of said lattice-mismatched semiconductor embedded in said thin-film (105), wherein said plurality of semiconductor needles (104, 204) are substantially vertically disposed in the axial direction toward said substrate (101) in said plurality of nanosize cavities (102, 102′) of said mask layer (103), and where a lattice-mismatched semiconductor epilayer (106) is provided on said thin-film supported thereby.

One or more 3D transistor structures that use one or more 2D materials as transistor channels along with methods for fabricating the same are disclosed. A 3D transistor can include a first carrier nanosheet at least partially surrounded by a first 2D material and a second carrier nanosheet at least partially surrounded by a second 2D material. The transistor can include a first source/drain structure in electrical contact with a first end of the first 2D material and a first end of the second 2D material. The transistor can include a second source/drain structure in electrical contact with a second end of the first 2D material and a second end of the second 2D material. The transistor can include a gate structure at least partially surrounding the first 2D material and the second 2D material.

One or more 3D transistor structures that use one or more 2D materials as transistor channels along with methods for fabricating the same are disclosed. A 3D transistor can include a first carrier nanosheet at least partially surrounded by a first 2D material and a second carrier nanosheet at least partially surrounded by a second 2D material. The transistor can include a first source/drain structure in electrical contact with a first end of the first 2D material and a first end of the second 2D material. The transistor can include a second source/drain structure in electrical contact with a second end of the first 2D material and a second end of the second 2D material. The transistor can include a gate structure at least partially surrounding the first 2D material and the second 2D material.

Methods for the manufacture of three-dimensional (3D) semiconductor devices are disclosed. Aspects can include forming a patterned first conductive source/drain structure of a transistor structure, forming a gate patterned conductive structure of the transistor structure separated from the first conductive source/drain structure by at least one dielectric layer, forming a patterned second conductive source/drain structure of the transistor structure separated from the gate patterned conductive structure by at least one dielectric layer, forming a transistor body opening extending through the transistor structure, forming a gate dielectric in the transistor body opening, and forming a material in the transistor body opening extending from the patterned first conductive source/drain structure to the patterned second conductive source/drain structure.

A method of manufacturing an electronic circuit (or circuit module) (100) is disclosed. The electronic circuit comprises a transistor (1) and a resistor (2), the transistor comprising a source terminal (11), a drain terminal (12), a gate terminal (13), and a first body (10) of material providing a controllable semi-conductive channel between the source and drain terminals, and the resistor comprises a first resistor terminal (21), a second resistor terminal (22), and a second body (20) of material providing a resistive current path between the first resistor terminal and the second resistor terminal. The method comprises: forming the first body (10); and forming the second body (20), wherein the first body comprises a first quantity (100) of a metal oxide and the second body comprises a second quantity (200) of said metal oxide. Corresponding electronic circuits are disclosed.

A method for making a metal oxide semiconductor carbon nanotube thin film transistor circuit. A p-type carbon nanotube thin film transistor and a n-type carbon nanotube thin film transistor are formed on an insulating substrate and stacked with each other. The p-type carbon nanotube thin film transistor includes a first semiconductor carbon nanotube layer, a first drain electrode, a first source electrode, a functional dielectric layer, and a first gate electrode. The n-type carbon nanotube thin film transistor includes a second semiconductor carbon nanotube layer, a second drain electrode, a second source electrode, a first insulating layer, and a second gate electrode. The first drain electrode and the second drain electrode are electrically connected with each other. The first gate electrode and the second gate electrode are electrically connected with each other.