A carbon nanoparticle and methods of making and using a carbon nanoparticle are provided. The carbon nanoparticle includes a reaction product of an organic reactant, an alkoxy amine, and an organometallic compound. The organometallic compound includes an element selected from the group consisting of a rare earth element, a transition metal element, and combinations thereof, and the carbon nanoparticle includes from 0.5 to 50 wt. % of the element. A method of making the carbon nanoparticle is also provided. The method includes combining the organic reactant, the alkoxy amine, and the organometallic compound into a mixture and heating the mixture such that the carbon nanoparticle forms. A method of determining a flow characteristic of a formation or an attribute of a fluid in a formation using the carbon nanoparticle is also provided.

The present invention relates to a method of producing a porous composite comprising single-atom metal catalysts and nitrogen atoms by using a hierarchical carbon material from a carbon dioxide-containing gas. According to the present invention, a composite material is produced by producing a porous carbon material using nanosized templates and carbon dioxide, producing carbon nanotubes from the composite material through a self-templating process, and adding single-atom catalysts to the carbon nanofibers. In addition, it is possible to produce a composite having significantly improved porous characteristics and electrochemical properties by nitrogen atom doping using a nitrogen precursor. The produced composite may be easily applied to a high-energy storage device such as a lithium-sulfur battery.

A nanocarbon separation method includes a step of preparing a dispersion liquid having nanocarbons dispersed therein; a step of injecting a liquid including the dispersion liquid into an electrophoresis tank so that a pH of the liquid increases from a bottom to a top in a direction of gravitational force; and a step of applying a direct current to electrodes disposed in an upper part and a lower part of the electrophoresis tank.

A method of forming nanoparticles having superhydrophobicity includes preparing a PDMS film including a structure having a predetermined shape on a surface thereof, and generating the nanoparticles having superhydrophobicity on the surface of the PDMS film by combusting the surface of the PDMS film using a diffusion flame. Transparent nanoparticles having superhydrophobicity and oleophobicity may be generated simply and easily on the surface of the PDMS film.

A method of forming nanoparticles having superhydrophobicity includes preparing a PDMS film including a structure having a predetermined shape on a surface thereof, and generating the nanoparticles having superhydrophobicity on the surface of the PDMS film by combusting the surface of the PDMS film using a diffusion flame. Transparent nanoparticles having superhydrophobicity and oleophobicity may be generated simply and easily on the surface of the PDMS film.

The present invention provides a method of manufacturing of an electrostatic self-assembled Silicon/rGO/carbon nanofibers composite, the method including: (a) obtaining a Si@APTES solution by adding predetermined Si nanoparticles to the piranha solution, and stirring, filtering, washing and drying, and then, dispersing the dried Si nanoparticles in deionized water, by adding APTES, and then stirring; (b) obtaining a Si@N-doped GO dispersion by mixing a mixture with the addition of urea (CH4N2O) to the GO solution and the prepared Si@APTES in step (a) in an ethanol aqueous solution; (c) obtaining a Si@N-doped GO/CNF composite by adding a predetermined CNF to the prepared Si@N-doped GO dispersion in step (b) and stirring it; and (d) obtaining a thermally reduced Si@N-doped rGO/CNF composite through a heat treatment process to the prepared Si@N-doped GO/CNF composite in step (c).

Disclosed are methods for providing a thin film of nanocrystalline diamond grown on 6 nm nanocrystalline diamond powder on the surface of substrates. The thin film of nanocrystalline diamond can be deposited on wide-bandgap semiconducting devices to provide heat dissipation characteristics to the semiconducting devices.

The disclosure provides a method of forming carbon dots, including admixing carbon powder with sulfuric acid and nitric acid and heating the carbon powder mixture to reflux to oxidize the carbon powder. The method further includes isolating and purifying the carbon dots. The disclosure further provides applications of the carbon dots for diagnostic analysis (such as bone analysis), fibrillation inhibition, and drug delivery.

The disclosure provides a method of forming carbon dots, including admixing carbon powder with sulfuric acid and nitric acid and heating the carbon powder mixture to reflux to oxidize the carbon powder. The method further includes isolating and purifying the carbon dots. The disclosure further provides applications of the carbon dots for diagnostic analysis (such as bone analysis), fibrillation inhibition, and drug delivery.

This utility invention is to replace some of the parts of current vehicles and robotic machines with intelligent graphene-based fibers and nanocomposites to achieve significantly weight-decreasing and energy-savings. This invention also is related to the formation of new generation vehicles, machine parts including robotics, which include but not limited to all kinds of cars, trailers, trucks, vehicles on roads and in the sky, ships on the ocean, and intelligent robotics for Human, as well as computer parts, bicycles, and sports supplies.