The present invention discloses a method for efficiently dispersing carbon nanotubes. The method comprises mixing, in parts by mass, 1-30 parts of carbon nanotubes, 0.2-10 parts of functionalized carbon nanotubes and 400-1200 parts of a solvent, adjusting the pH of the resulting mixture to 5-9, and then ultrasonically dispersing the mixture to obtain a stably dispersed carbon nanotube dispersion; the functionalized carbon nanotube is one or more of a carboxylated carbon nanotube, a hydroxylated carbon nanotube, an aminated carbon nanotube, an acyl-chlorinated carbon nanotube, and a sulfonated carbon nanotube.

The present invention belongs to the field of carbon materials and provides a precursor material and method for the preparation of carbon nanostructures. The invention directly uses rocks or mixtures of carbon raw materials with metal or metal oxide catalysts to prepare precursor materials. The precursor material is then wrapped by using metal wires and polarized in a molten salt system to prepare the nanostructured carbon material. Metals or metal oxides scattered in the carbon phase act as catalysts for the generation of nanostructured carbon materials; this precursor material can be easily obtained from natural rocks or by artificially synthesizing. Nanostructured carbon materials are composed of carbon nanoparticles, carbon fiber and carbon nanotubes. The preparation process is simple and easy to implement, and the resulting nanostructured material has high conductivity and can be used as an active material or additive for use in energy storage devices.

A fibrous carbon nanostructure dispersion liquid having excellent dispersibility of fibrous carbon nanostructures is provided. A fibrous carbon nanostructure dispersion liquid comprises: fibrous carbon nanostructures with a tap density of 0.024 g/cm.sup.3 or less; and a solvent.

A soft physiotherapy instrument includes a flexible sheet and a controller. The flexible sheet includes a first flexible layer, a second flexible layer, a plurality of functional layers located between the first flexible layer and the second flexible layer, and a plurality of electrodes electrically connected with the plurality of functional layers. The functional layer includes a carbon nanotube layer including a plurality of carbon nanotubes uniformly distributed. The flexible sheet is electrically coupled with the controller via the plurality of electrodes. A method for using the soft physiotherapy instrument is further provided.

A method for making nanomaterials includes introducing into a catalyzed reactor vessel: a carrier gas at a first carrier gas feed rate; at least one carbon-based reactant at a first reactant feed rate; and optionally, at least one additive at a first additive feed rate. The reactor vessel is heated to a first temperature of at least 150 C., so that a portion of the carbon-based reactant within the reactor vessel reacts to form a plurality of nanomaterials. An exhaust gas is removed from the reactor and periodically sampled by exposing a paper web to the gas so that a sample of the nanomaterials from the gas are deposited on a region of the paper web for analysis. Based on this analysis, at least one reaction parameter selected from the group consisting of the first carrier gas feed rate, the first reactant feed rate, and first temperature may be adjusted.

The present invention relates to entangled-type carbon nanotubes which have a bulk density of 31 kg/m.sup.3 to 85 kg/m.sup.3 and a ratio of tapped bulk density to bulk density of 1.37 to 2.05, and a method for preparing the entangled-type carbon nanotubes.

A method for fabricating an electron field emission cathode, the field emission cathode including a substrate having a field emission layer engaged therewith, where the field emission layer incorporates a carbon nanotube and metal composite film to improve adhesion between the material and the substrate and to improve field emission characteristics of the cathode and field emission cathode devices implementing such cathodes.

A method for fabricating an electron field emission cathode, the field emission cathode including a substrate having a field emission layer engaged therewith, where the field emission layer incorporates modified carbon nanotubes and a matrix material to improve field emission characteristics of the cathode and field emission cathode devices implementing such cathodes.

An embodiment of the disclosure provides a method for manufacturing a carbon nanotube using carbon dioxide and a carbon nanotube manufactured using carbon dioxide. Particularly, an embodiment of the disclosure provides a method for manufacturing a carbon nanotube using carbon dioxide to manufacture a uniform carbon nanotube with a small diameter by using a catalyst, a carbon raw material, and carbon dioxide, with a carbon nanotube manufactured using carbon dioxide.

The present invention belongs to the field of new materials technology and discloses a green method for preparing functionalized carbon materials. The present invention can use potassium ferrate(VI) as an oxidant and mechanical milling as a reaction technique for oxidizing carbon materials in a preparation of functionalized carbon materials having oxygen-containing functional groups. Compared with the prior art, the present invention provides a method that combines an environmentally friendly oxidant with an environmentally friendly reaction process. The oxidant potassium ferrate(VI) is a green oxidant without producing any toxic byproducts. The reaction process is solvent-free, facilitated by milling the solid mixture of carbon materials and the oxidant. Thus, the present invention provides an environmentally friendly method for preparing oxidatively functionalized carbon materials, which is of promotion value.