Nanocarbon separation device and nanocarbon separation method

The invention claimed is: 1. A nanocarbon separation device, comprising: 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 at a plurality of measurement positions in the separation tank; 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, wherein the plurality of measurement positions are arranged in a height direction of the separation tank. 2. The nanocarbon separation device according to claim 1 , wherein the evaluation unit is at least one of a unit that is configured to measure a potential of the dispersion liquid, a unit that is configured to measure a pH of the dispersion liquid, a unit that is configured to measure an absorbance of the dispersion liquid, a unit that is configured to measure an emission spectrum of the dispersion liquid, a unit that is configured to measure a refractive index of the dispersion liquid, a unit that is configured to measure a conductivity of the dispersion liquid, and a unit that is configured to measure a current value between the first electrode and the second electrode. 3. The nanocarbon separation method according to claim 1 , wherein the dispersion liquid includes a polyoxyethylene alkyl ether represented by the following formula as a non-ionic surfactant: C n H 2n (OCH 2 CH 2 ) m OH here, n=12 to 18, m=20 to 100. 4. The nanocarbon separation device according to claim 1 , wherein the determination unit is configured to determine that a separation of the metallic nanocarbons and the semiconducting nanocarbons has been completed. 5. The nanocarbon separation device according to claim 4 , wherein the determination unit is configured to determine that the separation has been completed when a measurement position at which a gradient of the physical state or the chemical state changes greatly becomes equal to or lower than a predetermined measurement position. 6. A nanocarbon separation method, comprising: injecting a dispersion liquid including nanocarbons into a separation tank; separating the metallic nanocarbons and the semiconducting nanocarbons by applying a direct current voltage between a first electrode provided at an upper part in the separation tank and a second electrode provided at a lower part in the separation tank, to cause metallic nanocarbons included in the dispersion liquid to move toward the first electrode, and to cause semiconducting nanocarbons included in the dispersion liquid to move toward the second electrode; evaluating a physical state or a chemical state of the dispersion liquid at a plurality of measurement positions in the separation tank; and determining a separation state of the metallic nanocarbons and the semiconducting nanocarbons from the physical state or the chemical state, wherein the plurality of measurement positions are arranged in a height direction of the separation tank. 7. The nanocarbon separation method according to claim 6 , wherein, in the evaluating the physical state or the chemical state, a separation state of the dispersion liquid is evaluated according to at least one of a potential of the dispersion liquid, a pH of the dispersion liquid, an absorbance of the dispersion liquid, an emission spectrum of the dispersion liquid, a refractive index of the dispersion liquid, a conductivity of the dispersion liquid and a current value between the first electrode and the second electrode. 8. The nanocarbon separation method according to claim 6 , comprising recovering the metallic nanocarbons and the semiconducting nanocarbons included in the dispersion liquid after the separating the metallic nanocarbons and the semiconducting nanocarbons. 9. The nanocarbon separation method according to claim 6 , wherein the nanocarbons are single-walled carbon nanotubes.