A method of separating and extracting carbon nanotubes, the method includes introducing the carbon nanotubes into a two-phase system that includes a first component and a second component, the first component being different from the second component. The method includes introducing a chemical agent into the two-phase system, mixing the chemical agent and the carbon nanotubes in the two-phase system, removing the first component to extract a first portion of the carbon nanotubes contained in the first component after the mixing, replenishing the two-phase system with fresh first component, and extracting a second portion of the carbon nanotubes contained in the fresh first component. A bandgap of the carbon nanotubes in the first portion is different from the bandgap of the carbon nanotubes in the second portion.

A manufacturing method for carbon nanotube composite film is disclosed. The method comprises steps of: providing a substrate; coating a first aqueous solution dissolved with a charged polymer on a substrate to form a polymer film; dispersing a single-wall carbon nanotube powder into a second aqueous solution dissolved with a charged compound in order to obtain a semiconductor-type single-wall carbon nanotube aqueous solution, and charge properties of the charged compound and the charged polymer are opposite; coating the semiconductor-type single-wall carbon nanotube aqueous solution on the polymer film; after standing for a predetermined period of time, washing with a deionized water to remove an unabsorbed semiconductor-type single-wall carbon nanotube and excess charged polymer; and air drying, forming a carbon nanotube film on the polymer film. A manufacturing method for carbon nanotube TFT and a carbon nanotube TFT are also disclosed. The carbon nanotubes can be well tiled onto the substrate.

A manufacturing method for carbon nanotube composite film is disclosed. The method comprises steps of: providing a substrate; coating a first aqueous solution dissolved with a charged polymer on a substrate to form a polymer film; dispersing a single-wall carbon nanotube powder into a second aqueous solution dissolved with a charged compound in order to obtain a semiconductor-type single-wall carbon nanotube aqueous solution, and charge properties of the charged compound and the charged polymer are opposite; coating the semiconductor-type single-wall carbon nanotube aqueous solution on the polymer film; after standing for a predetermined period of time, washing with a deionized water to remove an unabsorbed semiconductor-type single-wall carbon nanotube and excess charged polymer; and air drying, forming a carbon nanotube film on the polymer film. A manufacturing method for carbon nanotube TFT and a carbon nanotube TFT are also disclosed. The carbon nanotubes can be well tiled onto the substrate.

A nanocarbon separation device includes a separation tank that is configured to accommodate a dispersion liquid including nanocarbons, a first electrode provided at an upper part in the separation tank, a second electrode provided at a lower part in the separation tank, an evaluation unit that is configured to evaluate a physical state or a chemical state of the dispersion liquid, and a determination unit that is configured to determine a separation state between metallic nanocarbons and semiconducting nanocarbons included in the dispersion liquid from the physical state or the chemical state.

A nanocarbon separation device includes a separation tank that is configured to accommodate a dispersion liquid including nanocarbons, a first electrode provided at an upper part in the separation tank, a second electrode provided at a lower part in the separation tank, an evaluation unit that is configured to evaluate a physical state or a chemical state of the dispersion liquid, and a determination unit that is configured to determine a separation state between metallic nanocarbons and semiconducting nanocarbons included in the dispersion liquid from the physical state or the chemical state.

A nanocarbon separation device includes a separation tank that is configured to accommodate a dispersion liquid including nanocarbons, a first electrode that is provided at an upper part in the separation tank, a second electrode that is provided at a lower part in the separation tank, an evaluation unit that is configured to evaluate a physical state or a chemical state of the dispersion liquid, and a fractionation unit that is configured to fractionate the dispersion liquid based on the physical state or the chemical state.

A nanocarbon separation device includes a separation tank that is configured to accommodate a dispersion liquid including nanocarbons, a first electrode that is provided at an upper part in the separation tank, a second electrode that is provided at a lower part in the separation tank, an evaluation unit that is configured to evaluate a physical state or a chemical state of the dispersion liquid, and a fractionation unit that is configured to fractionate the dispersion liquid based on the physical state or the chemical state.

A nanocarbon separation device of the present invention includes a separation tank which is configured to accommodate a dispersion liquid including a nanocarbon, a first electrode that is provided at an upper part in the separation tank, a second electrode that is provided at a lower part in the separation tank, and a porous structure that is provided between the first electrode and the second electrode in the separation tank.

A nanocarbon separation device of the present invention includes a separation tank which is configured to accommodate a dispersion liquid including a nanocarbon, a first electrode that is provided at an upper part in the separation tank, a second electrode that is provided at a lower part in the separation tank, and a porous structure that is provided between the first electrode and the second electrode in the separation tank.

A single-walled carbon nanotube composition includes single-walled carbon nanotubes substantially enriched in semiconducting single-walled carbon nanotubes in association with a polymer having one or more oligoether side groups. The oligoether side groups render the composition dispersable in polar organic solvents, for example alkyl carbitols, permitting formulation of ink compositions containing single-walled carbon nanotubes substantially enriched in semiconducting single-walled carbon nanotubes. Such ink compositions may be readily printed using common printing methods, such as inkjet, flexography and gravure printing.