Porous and/or curved nanofiber bearing substrate materials are provided having enhanced surface area for a variety of applications including as electrical substrates, semipermeable membranes and barriers, structural lattices for tissue culturing and for composite materials, production of long unbranched nanofibers, and the like. A method of producing nanofibers is disclosed including providing a plurality of microparticles or nanoparticles such as carbon black particles having a catalyst material deposited thereon, and synthesizing a plurality of nanofibers from the catalyst material on the microparticles or nanoparticles. Compositions including carbon black particles having nanowires deposited thereon are further disclosed.

A method for forming nanostructures including introducing a hollow shell into a reactor. The hollow shell has catalyst nanoparticles exposed on its interior surface. The method also includes introducing a precursor into the reactor to grow nanostructures from the interior surface of the hollow shell from the catalyst nanoparticles.

A method for manufacturing a nanostructure composite material includes a step of preparing an inorganic material nanostructure, and a step of embedding an organic material to the inorganic material nanostructure so as to form the nanostructure composite material. In addition, a nanostructure composite material is also provided.

A method for making an organic light emitting diode includes providing a preform structure including an anode electrode, a hole transport layer, and an organic light emitting layer stacked on each other in that order. The organic light emitting layer has a first surface and a second surface opposite to the first surface, and the second surface is in direct contact with the hole transport layer. A carbon nanotube structure is located on the first surface. A monomer solution is disposed on the carbon nanotube structure, and the monomer solution is formed by dispersing a monomer into an organic solvent. The monomer is polymerized to form a polymer, and a cathode electrode is formed on the polymer.

The present disclosure generally relates to semiconductor structures and, more particularly, to self-aligned nanotube structures and methods of manufacture. The structure includes at least one nanotube structure supported by a plurality of spacers and an insulator material between the spacers and contacting the at least one nanotube structure.

A nano-vacuum tube (NVT) transistor comprising a source having a knife edge, a drain, and a channel formed between the source and the drain, the channel having a width to provide a pseudo-vacuum in a normal atmosphere. The NVT transistor utilizing a space charge plasma formed at the knife edge within the channel.

The invention relates to a method for manufacture of an electrical contact on a structure (10) made of an anisotropic material NA which exhibits an anisotropic electrical conductivity, where the structure (10) exhibits an axial electrical conductivity along a first axis XX of the structure (10) and an orthogonal conductivity along a direction YY orthogonal to the first axis XX of the structure (10), where the orthogonal conductivity is less than the axial conductivity, where the method comprises: a step for the formation of a conductive electrode (20), with an initial thickness Ei, comprising a species M, on a first surface (30) of the structure (10), where the first surface (30) is orthogonal to the orthogonal direction YY; the method being characterized in that the step for the formation of the conductive electrode (20) is followed by a step for implantation of species X through the conductive electrode (20), into the structure (10).

A semiconductor device includes a non-insulator structure, at least one carbon nano-tube (CNT), a dielectric layer, and a graphene-based conductive layer. The CNT is over the non-insulator structure. The dielectric layer surrounds the CNT. The graphene-based conductive layer is over the at least one CNT. The CNTs and the graphene-based conductive layer have low resistance.

Methods for passivating a nanotube fabric layer within a nanotube switching device to prevent or otherwise limit the encroachment of an adjacent material layer are disclosed. In some embodiments, a sacrificial material is implanted within a porous nanotube fabric layer to fill in the voids within the porous nanotube fabric layer while one or more other material layers are applied adjacent to the nanotube fabric layer. Once the other material layers are in place, the sacrificial material is removed. In other embodiments, a non-sacrificial filler material (selected and deposited in such a way as to not impair the switching function of the nanotube fabric layer) is used to form a barrier layer within a nanotube fabric layer. In other embodiments, individual nanotube elements are combined with and nanoscopic particles to limit the porosity of a nanotube fabric layer.

Embodiments of the invention include a method for fabricating a semiconductor device and the resulting structure. A substrate is provided. A plurality of metal portions are formed on the substrate, wherein the plurality of metal portions are arranged such that areas of the substrate remain exposed. A thin film layer is deposited on the plurality of metal portions and the exposed areas of the substrate. A dielectric layer is deposited, wherein the dielectric layer is in contact with portions of the thin film layer on the plurality of metal portions, and wherein the dielectric layer is not in contact with portions of the thin film layer on the exposed areas of the substrate such that one or more enclosed spaces are present between the thin film layer on the exposed areas of the substrate and the dielectric layer.