The present disclosure discloses a method for forming a high-density aligned carbon nanotube film. The method includes injecting a carbon nanotube solution into a container, and adding a dispersant to form a carbon nanotube-dispersant composite. The method also includes adding a substance that interacts with the carbon nanotube-dispersant composite and then dispersing the obtained carbon nanotube solution using water ultrasonic or probe ultrasonic to obtain a carbon nanotube solution containing a dispersant. Then a large-area or patterned high-quality aligned carbon nanotube film can be formed on a substrate by using processes such as pulling, injection dripping or printing. The method is low-cost and suitable for the preparation of large-area high-density aligned carbon nanotubes, and satisfies various needs for industrial application of carbon-based integrated circuits.

The present disclosure discloses a method for forming a high-density aligned carbon nanotube film. The method includes injecting a carbon nanotube solution into a container, and adding a dispersant to form a carbon nanotube-dispersant composite. The method also includes adding a substance that interacts with the carbon nanotube-dispersant composite and then dispersing the obtained carbon nanotube solution using water ultrasonic or probe ultrasonic to obtain a carbon nanotube solution containing a dispersant. Then a large-area or patterned high-quality aligned carbon nanotube film can be formed on a substrate by using processes such as pulling, injection dripping or printing. The method is low-cost and suitable for the preparation of large-area high-density aligned carbon nanotubes, and satisfies various needs for industrial application of carbon-based integrated circuits.

Provided herein is a nanopore structure, which in one aspect is a “carbon nanotube porin”, that comprises a short nanotube with an associated lipid coating. Also disclosed are compositions and methods enabling the preparation of such nanotube/lipid complexes. Further disclosed is a method for therapeutics delivery that involves a drug delivery agent comprising a liposome with a NT loaded with a therapeutic agent, introducing the therapeutic agent into a cell or a tissue or an organism; and subsequent release of the therapeutic agents into a cell.

Provided herein is a nanopore structure, which in one aspect is a “carbon nanotube porin”, that comprises a short nanotube with an associated lipid coating. Also disclosed are compositions and methods enabling the preparation of such nanotube/lipid complexes. Further disclosed is a method for therapeutics delivery that involves a drug delivery agent comprising a liposome with a NT loaded with a therapeutic agent, introducing the therapeutic agent into a cell or a tissue or an organism; and subsequent release of the therapeutic agents into a cell.

A method and system for substantially reducing iron and organic impurities in carbon nanotube materials.

A method and system for substantially reducing iron and organic impurities in carbon nanotube materials.

Carbon nanotube (CNT) hybrid materials and methods of making such materials. A carbon nanotube (CNT) hybrid powder material includes a mesh of CNTs intimately interspersed with particles of a second material. In an example the material includes a blend that itself includes particles of a metal oxide supported catalyst and particles of a second material, and a mesh of CNTs is grown on the supported catalyst in the blend. The mesh of CNTs is effective to disperse the particles of the second material.

A method for carbon nanotube purification, preferably including: providing carbon nanotubes; depositing a mask; and/or selectively removing a portion of the mask; and optionally including removing a subset of the carbon nanotubes and/or removing the remaining mask.

An electrode membrane having high adhesiveness and electrical conductivity can be produced using carbon nanotubes each of which meets the following requirements (1) and (2). (1) A peak appears at a diffraction angle 2θ=25°±2° in powder X-ray diffraction analysis, and the half value width of the peak is 2° or more and less than 3°. (2) The G/D ratio is 1.5 to 5.0, wherein G represents the maximum peak intensity in the range from 1560 to 1600 cm.sup.−1 and D represents the maximum peak intensity in the range from 1310 to 1350 cm.sup.−1 in Raman spectra.

Carbon nanotubes and dispersions containing carbon nanotubes are provided. Methods of processing carbon nanotubes and dispersions containing purified carbon nanotubes are provided.