A two-dimensional electronic component includes a substrate; an artificial two-dimensional (2D) material disposed on the substrate; and a first metallic electrode disposed on the artificial 2D material. The artificial 2D material includes a layered atomic structure including a middle atomic layer, a lower atomic layer disposed on a lower surface of the middle atomic layer, and an upper atomic layer disposed on an upper surface of the middle atomic layer respectively. The upper atomic layer and the first metallic electrode are attracted together at a junction therebetween by metallic bonding.

A transistor device having fin structures, source and drain terminals, channel layers and a gate structure is provided. The fin structures are disposed on a material layer. The fin structures are arranged in parallel and extending in a first direction. The source and drain terminals are disposed on the fin structures and the material layer and cover opposite ends of the fin structures. The channel layers are disposed respectively on the fin structures, and each channel layer extends between the source and drain terminals on the same fin structure. The gate structure is disposed on the channel layers and across the fin structures. The gate structure extends in a second direction perpendicular to the first direction. The materials of the channel layers include a transition metal and a chalcogenide, the source and drain terminals include a metallic material, and the channel layers are covalently bonded with the source and drain terminals.

A semiconductor device including a substrate, a semiconductor layer, a gate, a dielectric structure, and a source/drain structure is provided. The semiconductor layer is disposed on the substrate, and is made of a first low dimensional material. The gate is disposed on the substrate and overlaps the semiconductor layer. The dielectric structure is disposed on the semiconductor layer and includes a trench structure reaching a portion of the semiconductor layer. The source/drain structure includes a barrier layer made of a second low dimensional material continuously extending along the trench structure and a metal fill filling a volume surrounded by the barrier layer.

A memory device includes a substrate, an active layer spaced apart from a surface of the substrate and laterally oriented in a first direction and including an opened first side, a closed second side, and a channel layer between the first side and the second side, and a word line laterally oriented in a second direction crossing the first direction while surrounding the channel layer.

A method of making a graphene base transistor with reduced collector area comprising forming an electron injection region, forming an electron collection region, and forming a base region wherein the base region comprises one or more sheets of graphene and wherein the base region is intermediate the electron injection region and the electron collection region and forms electrical interfaces therewith.

A semiconductor device includes a substrate, a semiconductor structure suspending over the substrate and comprising a source region, a drain region, and a channel region disposed between the source region and the drain region. The channel region includes a doped two-dimensional (2D) material layer comprising a first portion on an upper surface of the channel region. The semiconductor device also includes an interfacial layer surrounding the channel region including the first portion of the doped 2D material layer, and a gate electrode surrounding the interfacial layer.

A method of making a graphene base transistor with reduced collector area comprising forming a graphene material layer, forming a collector material, depositing a dielectric, planarizing the dielectric, cleaning and removing the native oxide, transferring a base graphene material layer to the top surface of the graphene material layer, bonding the base graphene material layer, and photostepping and defining a second graphene material layer. A method of making a graphene base transistor with reduced collector area comprising forming an electron injection region, forming an electron collection region, and forming a base region. A graphene base transistor with reduced collector area comprising an electron emitter region, an electron collection region, and a base region.

Techniques and mechanisms for providing gate dielectric structures of a transistor. In an embodiment, the transistor comprises a thin channel structure which comprises one or more layers of a transition metal dichalcogenide (TMD) material. The channel structure forms two surfaces on opposite respective sides thereof, wherein the surfaces extend to each of two opposing edges of the channel structure. A composite gate dielectric structure comprises first bodies of a first dielectric material, wherein the first bodies each adjoin a different respective one of the two opposing edges, and variously extend to each of the surfaces two surfaces. The composite gate dielectric structure further comprises another body of a second dielectric material other than the first dielectric material. In another embodiment, the other body adjoins one or both of the two surfaces, and extends along one or both of the two surfaces to each of the first bodies.

Transistor structures with monocrystalline metal chalcogenide channel materials are formed from a plurality of template regions patterned over a substrate. A crystal of metal chalcogenide may be preferentially grown from a template region and the metal chalcogenide crystals then patterned into the channel region of a transistor. The template regions may be formed by nanometer-dimensioned patterning of a metal precursor, a growth promoter, a growth inhibitor, or a defected region. A metal precursor may be a metal oxide suitable, which is chalcogenated when exposed to a chalcogen precursor at elevated temperature, for example in a chemical vapor deposition process.

A transistor including a semiconductor channel including a compound semiconductor, and a source electrode and a drain electrode each electrically connected to the semiconductor channel and each independently including a topological conductor, wherein the compound semiconductor and the topological conductor include at least one metal element in common.