To reduce cost for the method for separating semiconducting carbon nanotube from a mixture of metallic and semiconducting carbon nanotubes. The separation method includes preparing a dispersion by mixing a first substance, a second substance, SDS, SC, and a mixture of metallic and semiconducting carbon nanotubes with a solvent, wherein the dispersion into two layers, which are a first layer mainly containing the first substance and a second layer mainly containing the second substance, whereby the semiconducting carbon nanotube is transferred into the first layer, and the metallic carbon nanotube is transferred into the second layer, wherein the first substance is an ?-glucan which is composed of glucose linked via ?-glucosidic linkage and which has a weight average molecular weight Mw of 4,000 to 7,000 and has a ratio in amount of ?-1, 6 linked glucose residues to the entire glucose residues of 40 to 70%.

Provided is an electrode mixture layer capable of reducing internal resistance by use of a carbon nanotube molding. The electrode mixture layer includes an active material and a conductor of carbon nanotubes in close contact with the surface of the active material, and the number density of the carbon nanotubes is 4 tubes/m or more. The number density is defined as a value obtained by providing measurement lines on a scanning electron microscope image of a surface of the electrode mixture layer at 0.3 m intervals both longitudinally and laterally, measuring the total number of the carbon nanotubes being in close contact with the surface of the active material and intersecting the measurement lines, and dividing the total number of the carbon nanotubes by the total length of the measurement lines on the active material surface.

Producing a semiconductor device having a semiconductor layer containing semiconducting carbon nanotube produced through a method including: mixing a first substance, a second substance which undergoes two-phase separation when mixed with the first substance in solution, an alkyl chain-containing surfactant, a steroidal surfactant, and a mixture of metallic and semiconducting carbon nanotubes with a solvent, to prepare a dispersion; and separating the dispersion into a first layer mainly containing the first substance and a second layer mainly containing the second substance, whereby the semiconducting carbon nanotube is transferred into one of the first and second layers, and the metallic carbon nanotube is transferred into the other layer; and the first substance is an -glucan composed of glucose linked via -glucosidic linkage and having a weight average molecular weight of 4,000 to 7,000 and a ratio of -1, 6 linked glucose residues to the entire glucose residues of 40 to 70%.

There is provided a carbon fiber-reinforced molded article that avoids peeling of carbon fibers from a base material and has high strength, the carbon fiber-reinforced molded article comprising a base material and a composite material dispersed in the base material, wherein the composite material comprises carbon fibers and a structure formed on the surface of the carbon fibers and including a plurality of carbon nanotubes, the plurality of carbon nanotubes forms a network structure in which the carbon nanotubes are directly connected to one another, and the plurality of carbon nanotubes is directly attached to the surface of the carbon fibers by using a portion of the surface thereof as an attaching portion, and also is physically bound to the surface of the carbon fibers via a binding member provided on at least a portion other than the attaching portion.

A nanotube-graphene hybrid nano-component and method for forming a cleaned nanotube-graphene hybrid nano-component. The nanotube-graphene hybrid nano-component includes a gate; a gate dielectric formed on the gate; a channel comprising a carbon nanotube-graphene hybrid nano-component formed on the gate dielectric; a source formed over a first region of the carbon nanotube-graphene hybrid nano-component; and a drain formed over a second region of the carbon nanotube-graphene hybrid nano-component to form a field effect transistor.

A method of manufacturing a metal composite material includes applying a mechanical impact force to a carbon material and a metal powder at such an intensity as capable of pulverizing the carbon material, thereby adhering the carbon material to a surface of the metal powder.

A nanotube-graphene hybrid film and method for forming a cleaned nanotube-graphene hybrid film. A method includes depositing nanotube film over a metal foil to produce a layer of nanotube film, placing the metal foil with as-deposited nanotube film in a chemical vapor deposition furnace to grow graphene on the nanotube film to form a nanotube-graphene hybrid film, and transferring the nanotube-graphene hybrid film over a substrate.

Withdrawing thermal energy obtained from a focused input of solar radiation can be complicated by issues associated with heat transfer media presently used for this purpose. By disposing carbon nanotubes on a fluidizable support and utilizing the carbon nanotubes as a fluidizable heat transfer medium, improved heat transfer characteristics can be realized due to the near-blackbody thermal absorption properties of the carbon nanotubes, in addition to other provided advantages. Concentrating solar power systems can include: a solar receiving structure configured to receive a focused input of solar radiation, a fluidized bed heat transfer medium within the solar receiving structure, and an energy-generating structure in thermal communication with the fluidized bed heat transfer medium. The fluidized bed heat transfer medium contains a plurality of fluidizable heat transfer particles, and the fluidizable heat transfer particles include a plurality of carbon nanotubes bonded to a plurality of fluidizable particles.