The current disclosure describes semiconductor devices, e.g., transistors, include a substrate, a semiconductor region including, at the surface, MoS.sub.2 and/or other monolayer material over the substrate, and a terminal structure at least partially over the semiconductor region, which includes a different monolayer material grown directly over the semiconductor region.

Provided are two-dimensional material (2D)-based wiring conductive layer contact structures, electronic devices including the same, and methods of manufacturing the electronic devices. A 2D material-based field effect transistor includes a substrate; first to third 2D material layers on the substrate; an insulating layer on the first 2D material layer; a source electrode on the second 2D material layer; a drain electrode on the third 2D material layer; and a gate electrode on the insulating layer. The first 2D material layer is configured to exhibit semiconductor characteristics, and the second and third 2D material layers are metallic 2D material layers. The first 2D material layer may include a first channel layer of a 2D material and a second channel layer of a 2D material. The first 2D material layer may partially overlap the second and third 2D material layers.

A method of fabricating semiconducting tellurium (Te) nanomesh. The method includes the steps of preparing a substrate, vaporizing Te powders under a first temperature; and growing Te nanomesh on the substrate using the vaporized Te powders under a second temperature. The first temperature is higher than the second temperature. The rationally designed nanomesh exhibits exciting properties, such as micrometer-level patterning capacity, excellent field-effect hole mobility, fast photoresponse in the optical communication region, and controllable electronic structure of the mixed-dimensional heterojunctions.

The current disclosure describes semiconductor devices, e.g., transistors, include a substrate, a semiconductor region including, at the surface, MoS.sub.2 and/or other monolayer material over the substrate, and a terminal structure at least partially over the semiconductor region, which includes a different monolayer material grown directly over the semiconductor region.

A template-assisted method for the synthesis of 2D nanosheets comprises growing a 2D material on the surface of a nanoparticle substrate that acts as a template for nanosheet growth. The 2D nanosheets may then be released from the template surface, e.g. via chemical intercalation and exfoliation, purified, and the templates may be reused.

A memory cell pillar of a memory device includes a heating electrode having a base portion (leg) and a fin portion (ascender), and a selection device between a first conductive line and the heating electrode. A side surface of the selection device and a side surface of the fin portion extend along a first straight line. A method of fabricating a memory device includes forming a plurality of first insulating walls through a stack structure including a preliminary selection device layer and a preliminary electrode layer, forming a plurality of self-aligned preliminary heating electrode layers, forming a plurality of second insulating walls each between two of the plurality of first insulating walls, and forming a plurality of third insulating walls in a plurality of holes extending along a direction intersecting the plurality of first insulating walls.

Embodiments of the invention are directed to methods and resulting structures for forming a storage element using phase change memory (PCM). In a non-limiting embodiment of the invention, a PCM layer is formed over a surface of a bottom electrode. A top electrode is formed over the PCM layer using a tone inversion process that includes a sacrificial layer. A PCM pillar is then formed by patterning the PCM layer to expose a surface of the bottom electrode. The tone inversion process enables a sub-50 nm PCM pillar diameter.

A memory cell pillar of a memory device includes a heating electrode having a base portion (leg) and a fin portion (ascender), and a selection device between a first conductive line and the heating electrode. A side surface of the selection device and a side surface of the fin portion extend along a first straight line. A method of fabricating a memory device includes forming a plurality of first insulating walls through a stack structure including a preliminary selection device layer and a preliminary electrode layer, forming a plurality of self-aligned preliminary heating electrode layers, forming a plurality of second insulating walls each between two of the plurality of first insulating walls, and forming a plurality of third insulating walls in a plurality of holes extending along a direction intersecting the plurality of first insulating walls.

Embodiments of the invention are directed to methods and resulting structures for forming a storage element using phase change memory (PCM). In a non-limiting embodiment of the invention, a PCM layer is formed over a surface of a bottom electrode. A top electrode is formed over the PCM layer using a tone inversion process that includes a sacrificial layer. A PCM pillar is then formed by patterning the PCM layer to expose a surface of the bottom electrode. The tone inversion process enables a sub-50 nm PCM pillar diameter.

Embodiments of the invention are directed to methods and resulting structures for forming a storage element using phase change memory (PCM). In a non-limiting embodiment of the invention, a PCM layer is formed over a surface of a bottom electrode. A top electrode is formed over the PCM layer using a tone inversion process that includes a sacrificial layer. A PCM pillar is then formed by patterning the PCM layer to expose a surface of the bottom electrode. The tone inversion process enables a sub-50 nm PCM pillar diameter.