The present invention relates to a method for synthesizing and collecting, in a single step, nanoparticles of different materials, and for producing coatings thereof on materials with simple or complex geometries, both in a controlled atmosphere and in ambient conditions, by means of the combined application of a laser beam and high-intensity electric fields.

A method for obtaining semiconducting carbon nanotubes is provided. An insulating substrate comprising hollow portions and non-hollow portions is provided. A plurality of electrodes is formed on a surface of the non-hollow portions. A plurality of carbon nanotubes is formed on a surface of the insulating substrate, and the carbon nanotubes stretches across the hollow portions. The insulating substrate, the plurality of electrodes, and the carbon nanotubes are placed into a cavity, and the cavity is evacuated. A voltage is applied between any two electrodes, and photos of carbon nanotubes suspended between the two electrodes are taken. In the photo, darker ones are the semiconducting carbon nanotubes, and brighter ones are metallic carbon nanotubes. Finally, the metallic carbon nanotubes are removed.

The present invention relates to a method for synthesizing and collecting, in a single step, nanoparticles of different materials, and for producing coatings thereof on materials with simple or complex geometries, both in a controlled atmosphere and in ambient conditions, by means of the combined application of a laser beam and high-intensity electric fields.

Methods and systems for separating carbon nanotubes are provided. An exemplary method of separating semiconducting carbon nanotubes and metallic carbon nanotubes contained within a solution can include providing electromagnetic waves travelling in one or more resonance modes and scattering at least a portion of the electromagnetic waves to form an electric gradient with the scattered waves. The method can further include recycling at least a portion of the scattered waves to the one or more resonance modes and separating at least a portion of the semiconducting carbon nanotubes and the metallic carbon nanotubes using the electric gradient.

Methods and systems for separating carbon nanotubes are provided. An exemplary method of separating semiconducting carbon nanotubes and metallic carbon nanotubes contained within a solution can include providing electromagnetic waves travelling in one or more resonance modes and scattering at least a portion of the electromagnetic waves to form an electric gradient with the scattered waves. The method can further include recycling at least a portion of the scattered waves to the one or more resonance modes and separating at least a portion of the semiconducting carbon nanotubes and the metallic carbon nanotubes using the electric gradient.

The separation of single-walled carbon nanotubes (SWNTs), by electronic type using centrifugation of compositions of SWNTs and surface active block copolymers in density gradient media.

A method for characterizing carbon nanotubes comprising: providing a conductive substrate and applying an insulating layer on the conductive substrate; forming a carbon nanotube structure on a surface of the insulating layer, the carbon nanotube structure includes at least one carbon nanotube; placing the carbon nanotube structure under a scanning electron microscope, adjusting the scanning electron microscope with an accelerating voltage ranging from 520 KV, a dwelling time ranging 620 microseconds and a magnification ranging from 10000100000 times; taking photos of the carbon nanotube structure with the scanning electron microscope; and, obtaining a photo of the carbon nanotube structure, the photo shows the at least one carbon nanotube and a background.

A method for characterizing carbon nanotubes comprising: providing a conductive substrate and applying an insulating layer on the conductive substrate; forming a carbon nanotube structure on a surface of the insulating layer, the carbon nanotube structure includes at least one carbon nanotube; placing the carbon nanotube structure under a scanning electron microscope, adjusting the scanning electron microscope with an accelerating voltage ranging from 520 KV, a dwelling time ranging 620 microseconds and a magnification ranging from 10000100000 times; taking photos of the carbon nanotube structure with the scanning electron microscope; and, obtaining a photo of the carbon nanotube structure, the photo shows the at least one carbon nanotube and a background.