A method is disclosed for producing an electron emitter (1) with a component surface (3) of which is coated with a coating (2) that contains nanorods (4, 7), in particular carbon nanotubes. According to said method, an elastomer film is applied and is then peeled off to obtain a surface from which carbon nanotubes (7) with an upright orientation project upward from an inorganic and electrically conductive adhesive layer (5). In another example, an overall coating region of the electron emitter (1) has an average number (n) of carbon nanotubes (7) with a predominantly upright orientation that project upward from the electrically conductive adhesive layer (5), the number of nanotubes (7) with a predominantly upright orientation per mm.sup.2 protruding from the adhesive layer deviating from the average value (n) by not more than 25% for each partial coating region of a size of at least 10.sup.8 mm.sup.2.

Polypropylene-coated functionalized multiwall carbon nanotubes (PP/f-MWNT) comprising functionalized multiwall carbon nanotubes (f-MWNT) in an amount of from about 0.5 wt. % to about 80 wt. %, based on the total weight of the PP/f-MWNT; and polypropylene (PP) in an amount of from about 20 wt. % to about 99.5 wt. %, based on the total weight of the PP/f-MWNT. A method of making PP/f-MWNT comprising (a) contacting pristine multiwall carbon nanotubes (p-MWNT) with nitric acid to produce f-MWNT; (b) contacting at least a portion of the f-MWNT with a first solvent to form a f-MWNT dispersion; (c) contacting PP with a second solvent to form a PP solution; (d) contacting at least a portion of the f-MWNT dispersion with at least a portion of the PP solution to form a PP and f-MWNT suspension; and (e) drying at least a portion of the PP and f-MWNT suspension to form the PP/f-MWNT.

A corrosion resistant material is described including a substrate, a first material including less than about 90% of an amino group or epoxy group, between about 0.05% and about 50% siloxane, between about 5% and about 80% nanoparticles, microparticles, or macroparticles, and between about 0.1% and about 5% of a first functionalized graphitic material, a second material including less than about 90% of a silyl group, between about 0.05% and about 50% siloxane, between about 5% and about 80% nanoparticles, microparticles, or macroparticles, and between about 0.1% and about 5% of a second functionalized graphitic material, and a third material including less than about 90% of an amino group or epoxy group and a silyl group, between about 0.05% and about 50% siloxane, between about 5% and about 80% nanoparticles, microparticles, or macroparticles, and between about 0.1% and about 5% of a third functionalized graphitic material.

Provided are a method of efficiently producing a fibrous carbon nanostructure dispersion liquid having high dispersibility, and a fibrous carbon nanostructure dispersion liquid having high dispersibility. A production method for a fibrous carbon nanostructure dispersion liquid comprises a step of performing continuous centrifugal separation on a solution containing fibrous carbon nanostructures and a solvent.

Described herein are processes and apparatus for the large-scale synthesis of boron nit ride nanotubes (BNNTs) by induction-coupled plasma (ICP). A boron-containing feedstock may be heated by ICP in the presence of nitrogen gas at an elevated pressure, to form vaporized boron. The vaporized boron may be cooled to form boron droplets, such as nanodroplets. Cooling may take place using a condenser, for example. BNNTs may then form downstream and can be harvested.

A method for preparing a preblend of nanostructured carbon, such as nanotubes, fullerenes, or graphene, and a particulate solid, such as polymer beads, carbon black, graphitic particles or glassy carbon involving wet-mixing and followed by optional drying to remove the liquid medium. The preblend may be in the form of a core-shell powder material with the nanostructured carbon as the shell on the particulate solid core. The preblend may provide particularly improved dispersion of single-walled nanotubes in ethylene--olefin elastomer compositions, resulting in improved reinforcement from the nanotubes. The improved elastomer compositions may show simultaneous improvement in both modulus and in elongation at break. The elastomer compositions may be formed into useful rubber articles.

Disclosed herein is a conductive grease composition that includes a functionalized carbon nanomaterial and/or boron nanomaterial and a base oil. The nanomaterial and base oil forms hydrogen bond network in the disclosed composition. Because of the formed hydrogen bonds, the disclosed grease exhibits enhanced thermal or electrical conductivity. Also disclosed is a method to improve thermal or electrical conductivity of an existing grease composition.

A method is disclosed for producing an electron emitter (1) with a component surface (3) of which is coated with a coating (2) that contains nanorods (4, 7), in particular carbon nanotubes. According to said method, an elastomer film is applied and is then peeled off to obtain a surface from which carbon nanotubes (7) with an upright orientation project upward from an inorganic and electrically conductive adhesive layer (5). In another example, an overall coating region of the electron emitter (1) has an average number (n) of carbon nanotubes (7) with a predominantly upright orientation that project upward from the electrically conductive adhesive layer (5), the number of nanotubes (7) with a predominantly upright orientation per mm.sup.2 protruding from the adhesive layer deviating from the average value (n) by not more than 25% for each partial coating region of a size of at least 10.sup.8 mm.sup.2.

A method for oxidizing multi-walled carbon nanotubes is provided. At least one multi-walled carbon nanotube is provided. The at least one multi-walled carbon nanotube is placed into a heating furnace filled with carbon dioxide gas. The heating furnace is heated to a temperature ranged from about 800 C. to about 950 C., and the at least one multi-walled carbon nanotube is oxidized in the carbon dioxide.

To provide a method for manufacturing carbon nanotubes and a carbon nanotube manufacturing device capable of manufacturing carbon nanotubes with a high yield. A first manufacturing device 100 mainly includes a mass flow controller 110, a growth furnace 120, a quartz tube 130, a pressure gauge 150, an electromagnetic valve 160, a pressure adjustment valve 170, and a needle valve 180. The quartz tube 130 is a cylindrical tube made of quartz, and is inserted into the growth furnace 120. The inside of the growth furnace 120 can be adjusted to a temperature suitable for the thermal decomposition temperature of each raw material resin. The pressure gauge 150 is connected to an outlet pipe 104 extending from an outlet end of the quartz tube 130. The electromagnetic valve 160 receives a pressure value from the pressure gauge 150, and opens/closes a pipe 106 according to the pressure value. The raw material resin 144 is placed near an inlet end of the growth furnace 120. A catalyst metal 142 is placed at a position separated by a predetermined distance from the inlet end of the growth furnace 120.