The present invention relates to cross-linked and recyclable nanocompounds obtained by in situ terminal treatment of raw carbonaceous materials, including charcoal, tar, activated carbon, pyrolytic carbon, coke, graphite or others having conductive structures, including graphite, graphene, different carbon nanotubes, fullerenes or a combination thereof or their derivatives, and a polymer capable of dispersing and reversibly stabilising said components, having viscous or fluid behaviour below 200° C., and may have pendant groups acting as diene or dienophile, including furan-functionalised aliphatic polyketones, furan-functionalised polyesters, ethylene rubber with propylene functionalised with furan groups or a combination thereof. Derived materials, method of obtainment and their uses as a thermostable, thermoreversible, thermoadhesive, thermoconductive, electroconductive, self-repairing additive or matrix capable of converting electricity into heat or a combination thereof and in self-assembling or self-repairing, thermoconductive, electroconductive materials capable of converting electricity into heat or a combination thereof.

The present invention relates to cross-linked and recyclable nanocompounds obtained by in situ terminal treatment of raw carbonaceous materials, including charcoal, tar, activated carbon, pyrolytic carbon, coke, graphite or others having conductive structures, including graphite, graphene, different carbon nanotubes, fullerenes or a combination thereof or their derivatives, and a polymer capable of dispersing and reversibly stabilising said components, having viscous or fluid behaviour below 200° C., and may have pendant groups acting as diene or dienophile, including furan-functionalised aliphatic polyketones, furan-functionalised polyesters, ethylene rubber with propylene functionalised with furan groups or a combination thereof. Derived materials, method of obtainment and their uses as a thermostable, thermoreversible, thermoadhesive, thermoconductive, electroconductive, self-repairing additive or matrix capable of converting electricity into heat or a combination thereof and in self-assembling or self-repairing, thermoconductive, electroconductive materials capable of converting electricity into heat or a combination thereof.

Nanoassembly methods for producing quasi-3D plasmonic films with periodic nanoarrays of nano-sized surface features. A sacrificial layer is deposited on a surface of a donor substrate having periodic nanoarrays of nanopattern features formed thereon. A plasmon film is deposited onto the sacrificial layer and a dielectric spacer is deposited on the plasmon film. The donor substrate having the sacrificial layer, plasmon film, and dielectric spacer thereon is immersed in a bath of etchant to selectively remove the sacrificial layer such that the plasmon film and the dielectric spacer thereon adhere to the surface of the donor substrate. The dielectric spacer and the plasmon film are mechanically separated from the donor substrate to define a quasi-three dimensional (3D) plasmonic film having periodic nanoarrays of nano-sized surface features defined by the nanopattern features of the donor substrate surface. The quasi-3D plasmonic film is then applied to a receiver substrate.

A porous composite structure including a substrate including a plurality of nanostructures; a particle layer disposed on a surface of the substrate; and a liquid, a method of preparing the porous composite structure, an article including the porous composite structure, and an air purifier including the porous composite structure.

The present invention discloses a nanoparticle control and detection system and operating method thereof. The present invention controls and detects the nanoparticles in the same device. The device comprises a first transparent electrode, a photoconductive layer, a spacer which is deposed on the edge of the photoconductive layer and a second transparent electrode. The aforementioned device controls and detects the nanoparticles by applying AC/DC bias and AC/DC light source to the transparent electrode.

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 for producing a Group III-V semiconductor nanoparticle by flow reaction, including: introducing a solution of compound containing Group III element into a first flow channel, introducing a solution of compound containing Group V element into a second flow channel, and combining the solutions to produce nanoparticles, in which the combining portion is constituted by a multi-layered tubular mixer, one of the solutions is allowed to flow through a flow channel in the smallest tube of the mixer, and the other of the solutions is allowed to flow through a flow channel adjacent to the flow channel in the smallest tube, and a value of a ratio of linear velocity of the solution flowing in the flow channel adjacent to the flow channel in the smallest tube to linear velocity of the solution flowing in the flow channel in the smallest tube is a specific value.

A method for producing a Group III-V semiconductor nanoparticle by flow reaction, including: introducing a solution of compound containing Group III element into a first flow channel, introducing a solution of compound containing Group V element into a second flow channel, and combining the solutions to produce nanoparticles, in which the combining portion is constituted by a multi-layered tubular mixer, one of the solutions is allowed to flow through a flow channel in the smallest tube of the mixer, and the other of the solutions is allowed to flow through a flow channel adjacent to the flow channel in the smallest tube, and a value of a ratio of linear velocity of the solution flowing in the flow channel adjacent to the flow channel in the smallest tube to linear velocity of the solution flowing in the flow channel in the smallest tube is a specific value.

A quantum dot, a light emitting material, and a manufacturing method of quantum dot are provided. A ratio of an emission intensity to an absorption intensity of the quantum dot at a characteristic wavelength ranges from 1.5×10.sup.8 CPS/Abs. to 2.0×10.sup.9 CPS/Abs. The characteristic wavelength is a shorter wavelength of two wavelengths corresponding to half of a maximum intensity of an emission peak of the quantum dot.

Nanoassembly methods for producing quasi-3D plasmonic films with periodic nanoarrays of nano-sized surface features. A sacrificial layer is deposited on a surface of a donor substrate having periodic nanoarrays of nanopattern features formed thereon. A plasmon film is deposited onto the sacrificial layer and a dielectric spacer is deposited on the plasmon film. The donor substrate having the sacrificial layer, plasmon film, and dielectric spacer thereon is immersed in a bath of etchant to selectively remove the sacrificial layer such that the plasmon film and the dielectric spacer thereon adhere to the surface of the donor substrate. The dielectric spacer and the plasmon film are mechanically separated from the donor substrate to define a quasi-three dimensional (3D) plasmonic film having periodic nanoarrays of nano-sized surface features defined by the nanopattern features of the donor substrate surface. The quasi-3D plasmonic film is then applied to a receiver substrate.