A microelectronic device includes a gated graphene component. The gated graphene component has a graphitic layer containing one or more layers of graphene. The graphitic layer has a channel region, a first contact region adjacent to the channel region and a second contact region adjacent to the channel region. A patterned hexagonal boron nitride (hBN) layer is disposed on the graphitic layer above the channel region. A gate is located over the patterned hBN layer above the channel region. A first connection is disposed on the graphitic layer in the first contact region, and a second connection is disposed on the graphitic layer in the second contact region. The patterned hBN layer does not extend completely under the first connection or under the second connection. A method of forming the gated graphene component in the microelectronic device is disclosed.

A semiconductor device and method for forming the same. The device comprises at least a dielectric layer, a two-dimensional (2D) material layer, a gate structure, and source/drain contacts. The 2D material layer contacts the dielectric layer. The gate structure contacts the 2D material layer. The source/drain contacts are disposed above the 2D material layer and contact the gate structure. The method includes forming a structure including at least a handle wafer, a 2D material layer, a gate structure in contact with the 2D material layer, an insulating layer, and a sacrificial layer. A portion of the sacrificial layer is etched. An inter-layer dielectric is formed in contact with the insulating layer and sidewalls of the sacrificial layer. The sacrificial layer and a portion of the insulating layer are removed. Source and drain contacts are formed in contact with the portion of the 2D material layer.

A GAA transistor includes a semiconductor substrate. A first shallow trench isolation (STI) is embedded in the semiconductor substrate. A top surface of the first STI is lower than a top surface of the semiconductor substrate. A nanowire crosses the first STI and is disposed on the first STI. A gate structure contacts and wraps around the nanowire. A source electrode contacts a first end of the nanowire. A drain electrode contacts a second end of the nanowire.

A field effect transistor includes a substrate, a source electrode and a drain electrode on the substrate and apart from each other in a first direction, a plurality of channel layers, a gate insulating film surrounding each of the plurality of channel layers, and a gate electrode surrounding the gate insulating film. Each of the plurality of channel layers has ends contacting the source electrode and the drain electrode. The plurality of channel layers are spaced apart from each other in a second direction away from the substrate. The plurality of channel layers include a 2D semiconductor material.

Semiconductor devices and methods of forming the same are provided. A semiconductor device according to the present disclosure includes a channel member including a first channel layer and a second channel layer over the first channel layer, and a gate structure over the channel member. The first channel layer includes silicon, germanium, a III-V semiconductor, or a II-VI semiconductor and the second channel layer includes a two-dimensional material.

Precision and chip contamination-free placement of two-dimensional (2D) material and van der Waals (VDW) layered materials accelerates both the study of fundamental properties and novel device functionality. The system transfers 2D materials utilizing a combination of a narrow transfer-stamper and viscoelastic and optically transparent film. Precise placement of individual 2D materials results in vanishing cross-contamination to the substrate. The 2D printer results in an aerial cross-contamination improvement of two to three orders of magnitude relative to state-of-the-art transfer methods from a source of average area sub um{circumflex over ( )}2. The transfer-stamper does not physically harm any micro/nanostructures preexisting on the target substrates receiving the 2D material such as, nanoelectronics, waveguides or micro-ring resonators. Such accurate and substrate-benign transfer method for 2D and VDW layered materials provides rapid device prototyping due to its high time-reduction, accuracy, and contamination-free process.

A finFET device that includes a substrate and at least one semiconductor fin extending from the substrate. The fin may include a plurality of wide portions comprising a first semiconductor material and one or more narrow portions. The one or more narrow portions have a second width less than the first width of the wide portions. Each of the one or more narrow portions separates two of the plurality of wide portions from one another such that the plurality of wide portions and the one or more narrow portions are arranged alternatingly in a substantially vertical direction that is substantially perpendicular with a surface of the substrate. The fin may also include a channel layer covering sidewalls of the plurality of wide portions and a sidewall of the one or more narrow portions.

A transistor comprising a channel region on a material is disclosed. The channel region comprises a two-dimensional material comprising opposing sidewalls and oriented perpendicular to the material. A gate dielectric is on the two-dimensional material and gates are on the gate dielectric. Semiconductor devices and systems including at least one transistor are disclosed, as well as methods of forming a semiconductor device.

In an embodiment, a device includes: a dielectric fin on a substrate; a low-dimensional layer on the dielectric fin, the low-dimensional layer including a source/drain region and a channel region; a source/drain contact on the source/drain region; and a gate structure on the channel region adjacent the source/drain contact, the gate structure having a first width at a top of the gate structure, a second width at a middle of the gate structure, and a third width at a bottom of the gate structure, the second width being less than each of the first width and the third width.

The field-effect mobility and reliability of a transistor including an oxide semiconductor film are improved. A semiconductor layer of a transistor is formed using a composite oxide semiconductor in which a first region and a second region are mixed. The first region includes a plurality of first clusters containing one or more of indium, zinc, and oxygen as a main component. The second region includes a plurality of second clusters containing one or more of indium, an element M (M represents Al, Ga, Y, or Sn), zinc, and oxygen. The first region includes a portion in which the plurality of first clusters are connected to each other. The second region includes a portion in which the plurality of second clusters are connected to each other.