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.

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.

A switchable array includes: a microstructure of interconnected units formed of graphene tubes with open spaces in the microstructure bounded by the graphene tubes; at least one JFET gate in at least one of the graphene tubes; and a control line having an end connected to the at least one JFET gate. The control line extends to a periphery of the microstructure.

Provided by the inventive concept are electronic devices, such as semiconductor devices, including p-type oxide materials having and selected for having improved hole mobilities, band gaps, and phase stability, and methods for fabricating electronic devices having such p-type oxide materials.

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.

A capacitive device includes: a first metal plate; a first planar dielectric layer disposed on the first metal plate; a second planar dielectric layer disposed on the first planar dielectric layer; a third planar dielectric layer disposed on the second planar dielectric layer; and a second metal plate disposed on the third planar dielectric layer; wherein the first planar dielectric layer has a first dielectric constant, the second planar dielectric layer has a second dielectric constant, and the third planar dielectric layer has a third dielectric constant, and the second dielectric constant is different from the first dielectric constant and the third dielectric constant, the second planar dielectric layer includes Tantalum pentoxide.

A capacitive device includes: a first metal plate; a first planar dielectric layer disposed on the first metal plate; a second planar dielectric layer disposed on the first planar dielectric layer; a third planar dielectric layer disposed on the second planar dielectric layer; and a second metal plate disposed on the third planar dielectric layer; wherein the first planar dielectric layer has a first dielectric constant, the second planar dielectric layer has a second dielectric constant, and the third planar dielectric layer has a third dielectric constant, and the second dielectric constant is different from the first dielectric constant and the third dielectric constant, the second planar dielectric layer includes Tantalum pentoxide.

A TFT structure based on a flexible multi-layer graphene quantum carbon substrate material and a method for manufacturing the same. The TFT structure includes a multi-layer graphene quantum carbon substrate, a first source, a first drain, a first gate insulating layer, and a first gate. The multi-layer graphene quantum carbon substrate includes a first channel area, and a first drain area and a first source area that are located at corresponding recessed positions on the multi-layer graphene quantum carbon substrate that are separated from each other. The first channel area is located between the first drain area and the first source area, the first source is filled in the first source area, the first drain is filled in the first drain area, the first gate insulating layer is disposed on the first channel area, and the first gate is disposed on the first gate insulating layer.

A TFT structure based on a flexible multi-layer graphene quantum carbon substrate material and a method for manufacturing the same. The TFT structure includes a multi-layer graphene quantum carbon substrate, a first source, a first drain, a first gate insulating layer, and a first gate. The multi-layer graphene quantum carbon substrate includes a first channel area, and a first drain area and a first source area that are located at corresponding recessed positions on the multi-layer graphene quantum carbon substrate that are separated from each other. The first channel area is located between the first drain area and the first source area, the first source is filled in the first source area, the first drain is filled in the first drain area, the first gate insulating layer is disposed on the first channel area, and the first gate is disposed on the first gate insulating layer.

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.